Abstract
Skin regeneration is severely compromised in diabetic foot ulcers. Allogeneic mesenchymal stem cell (MSC) transplantation is limited due to the poor engraftment, mitogenic, and differentiation potential in the harsh wound microenvironment. Thus, to improve the efficacy of cell therapy, the chemokine receptor Cxcr2 was overexpressed in MSCs (MSCCxcr2). CXCL2/CXCR2 axis induction led to the enhanced proliferation of MSCs through the activation of STAT3 and ERK1/2 signaling. Transcriptional upregulation of FGFR2IIIb (KGF Receptor) promoter by the activated STAT3 and ERK1/2 suggested trans-differentiation of MSCs into keratinocytes. These stable MSCCxcr2 in 2D and 3D (spheroid) cell cultures efficiently transdifferentiated into keratinocyte-like cells (KLCs). An in vivo therapeutic potential of MSCCxcr2 transplantation and its keratinocyte-specific cell fate was observed by accelerated skin tissue regeneration in an excisional splinting wound healing murine model of streptozotocin-induced type 1 diabetes. Finally, 3D skin organoids generated using MSCCxcr2-derived KLCs upon grafting in a relatively avascular and non-healing wounds of type 2 diabetic db/db transgenic old mice resulted in a significant enhancement in the rate of wound closure by increased epithelialization (epidermal layer) and endothelialization (dermal layer). Our findings emphasize the therapeutic role of the CXCL2/CXCR2 axis in inducing trans-differentiation of the MSCs toward KLCs through the activation of ERK1/2 and STAT3 signaling and enhanced skin regeneration potential of 3D organoids grafting in chronic diabetic wounds.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Cutaneous wound healing is a complex dynamic process involving four overlapping stages—hemostasis, inflammation, cellular proliferation, and remodeling [1]. These processes result in a synchronized network of repair mechanisms like cell migration, proliferation, and tissue regeneration orchestrated by an interplay of cytokines, growth factors, extracellular matrix, and chemokines. The wound healing processes are severely impaired in patients with metabolic diseases like diabetes [2] and pathophysiological skin conditions like atopic dermatitis [3, 4], and psoriasis [5]. The resident cells within the wound microenvironment, such as fibroblasts, keratinocytes, and endothelial cells, are functionally compromised in patients with diabetic foot ulcers (DFU) due to persistent hyperglycemia that delays the healing process resulting in chronic non-healing wounds [1]. DFU is a major complication associated with diabetes mellitus. Approximately 19–34% of diabetic patients worldwide are at risk of developing DFU in their lifetime [6]. The process of wound healing in diabetic patients remains incomplete due to the downregulation of cytokines and growth factors, such as platelet-derived growth factor (PDGF), vascular endothelial growth factor (VEGF), keratinocyte growth factor (KGF), epidermal growth factor (EGF), transforming growth factor beta 1 (TGFβ1), insulin growth factor 1 (IGF-1), interleukin 6, and TNF-α [7]. The physiological functions of keratinocytes are impaired due to hyperglycemia and increased ROS, advanced glycation end products (AGEs), proinflammatory cytokines, and mitochondrial dysfunction, resulting in delayed wound healing [8]. Recent studies have demonstrated the crucial role of chemokines, which are a family of heparin-binding cytokines typically mediating directional migration and leukocyte trafficking, and their cognate receptors substantiate the recruitment of leukocyte subtypes during wound healing [9,10,11]. Functionally chemokines may be classified as pro-inflammatory, which are expressed by leukocytes and other cells only upon activation, and homeostatic, which are constitutively expressed. Thus, chemokines receptors can serve as useful bait to recruit the target cells for modulating the physiological processes in chronic wounds [12].
Mesenchymal stem cells (MSCs) are promising candidates for cell therapies for skin tissue regeneration in chronic wounds due to their ability to transdifferentiate into multiple cell lineages and low immunogenicity. Though the therapeutic potential of MSCs has been demonstrated in several preclinical studies, particularly in cutaneous regeneration [13], MSC transplantation has demonstrated limited success to enhance wound healing in clinical settings of chronic diabetic wounds [14, 15]. A major drawback of MSC transplantation is due to its low engraftment, survival rate, and retort time to transdifferentiate in different lineages, which limits its clinical application. MSCs potentiate the repair and regeneration of injured tissues by modulating chemokine ligand–receptor interactions. Prior studies from our lab have demonstrated a higher expression of the chemokine ligand CXCL2 in the wound bed during the healing period [16]. This incited us to evaluate the effect of Cxcr2 (the cognate receptor of CXCL2) modulation in MSC physiology. We demonstrated the transcriptional regulation and molecular mechanism of Cxcr2-mediated enhanced MSC trans-differentiation into keratinocytes-like cells (KLCs) in vitro and the efficacy of Cxcr2-bioengineered MSCs transplantation therapy for skin regeneration in the excisional splinting wound healing model in type 1 diabetic mice. Furthermore, we generated 3D skin organoids using Cxcr2-bioengineered MSC,derived KLCs and fibroblasts to evaluate the efficacy of these 3D organoid grafting-mediated skin regeneration by increased epithelialization (epidermal layer—keratinocytes), and vascularity (dermal layer) in type 2 diabetic transgenic db/db mice.
Materials and methods
Cell culture studies
Mouse bone marrow-derived mesenchymal stem cells (MSCs) (Cyagen, Santa Clara, USA) were cultured in α-MEM medium (HiMedia, Mumbai, India) supplemented with 10% fetal bovine serum (FBS) and 1% penicillin–streptomycin (Gibco, Billings, USA). Cells were maintained at 5% CO2 at 37 °C in a humidified atmosphere [16].
Gene cloning studies
Sub-cloning of Cxcr2 gene on lentiviral vector for stable overexpression and/or silencing: Cxcr2-MycDDK gene insert was sub-cloned from pCMV-Cxcr2-MycDDK plasmid vector into the TurboGFP region of the lentiviral vector pCW57-TurboGFP-2a-MCS as described previously [17]. Lentiviral particles were generated by co-transfecting HEK-293T cells with the packaging vectors psPAX2, and pMD2.G along with pCW57-Cxcr2MycDDK, pCW57-TurboGFP, piLenti-Scrambled shRNA-GFP, and/or piLenti-Cxcr2 shRNA-GFP (ABM, Richmond, CA) using Lipofectamine 3000 (ThermoFisher, Waltham, USA). MSCs were transduced with the lentiviral particles using polybrene (10 μg/ml) and doxycycline (5 μg/ml) for transgene induction and subsequently subjected to puromycin selection (5 μg/ml) as described earlier [16, 17]. Gene cloning protocols were performed with prior approval of the Institutional Biosafety Committee (Approval No. IICT/IBSC/03/2019).
Generation of bioengineered MSCs with stable Cxcr2 overexpression and/or silencing: MSCs were either transiently transfected with the plasmid vectors pCMV-Cxcr2-Myc,dDK and/or pCMV-EGFP (control) or separately transfected with the lentiviral construct pCW57-Cxcr2-MycDDK-2a-MCS and/or pCW57-TurboGFP-2a-MCS (control) and for the silencing of the Cxcr2 gene by transfecting the MSCs with piLenti-Cxcr2-shRNA-GFP and/or piLenti-Scr-shRNA-GFP (control). These transfected MSCs were subjected to RNA and protein isolation post 48 h and 72 h, respectively of culture [16].
Promoter–reporter studies
In silico analysis: FGFR2IIIb (KGF Receptor, KGFR) promoter up to 5 kb upstream to the transcription start site confirmed the presence of one STAT3-binding site (BS) and four proximal SP1-binding sites (BS). Seven promoter–reporter constructs bearing all the transcription factor-binding sites (TFBS) depicted as Wild type (WT) and with sequential deletion of binding sites (e.g., ΔBS1) were designed and cloned as described previously [16].
Promoter cloning studies: Two constructs of the FGFR2IIIb promoter were designed containing the STAT3 BS (FGFR2IIIb STAT3 WT—179 bp), and deletion construct without STAT3 BS (FGFR2IIIb Δ STAT3—86 bp) was cloned from mouse skin DNA using the restriction enzymes EcoRI and BamHI into the vector pMCS-Green Renilla Luc plasmid vector (ThermoFisher, Waltham, USA) as described previously [17]. Similarly, five constructs of the FGFR2IIIb promoter were designed containing four proximal SP1-binding sites (SP1 BS1-4), (FGFR2IIIb ERK WT—380 bp), three proximal SP1 BS (FGFR2IIIb ERK ΔBS4—140 bp), two proximal SP1 BS (FGFR2IIIb ERK ΔBS4 + 3—103 bp), one proximal SP1 BS (FGFR2IIIb ERK ΔBS4 + 3 + 2—91 bp), and no SP1 BS (FGFR2IIIb ERK ΔBS4 + 3 + 2 + 1—62 bp) and were cloned from mouse skin DNA using the restriction enzymes EcoR1 and BamH1 into the vector pMCS-Green Renilla Luc plasmid vector as described previously [16, 17].
Promoter–Reporter dual luciferase assay: Cxcr2-bioengineered MSCs with stable overexpression (MSCCxcr2) and/or silencing (MSCCxcr2 KD) along with their respective controls (MSCGFP and MSCScrKD) were plated in a 96-well plate at a cell density of 104 cells/well and incubated for 24h at 37 °C. These Cxcr2-bioengineered MSCs were transfected with pMCS-Green Renilla Luc vector subcloned with the desired promoter region of mouse FGFR2IIIb (KGFR) and internal control vector (pCMV-Red Firefly Luc) using Lipofectamine 3000 (Invitrogen, USA). 24h post-transfection, these Cxcr2-bioengineered MSCs were treated with CXCL2 in absence or presence of pharmacological inhibitors of CXCR2–SB265610, ERK—PD98059, and STAT3—S3I201 at 37 °C for 72h. Promoter–reporter assays were performed according to the manufacturer's protocol [17].
Gene and Protein expression studies
Quantitative-Polymerase Chain Reaction (qPCR) analysis: Total RNA was extracted from the bioengineered MSCs with stable Cxcr2 overexpression and/or silencing followed by cDNA synthesis. The cDNA was subjected to qPCR analysis using mouse gene-specific primers (Table ST1) to calculate the relative fold change of various epithelial and keratinocyte lineage-specific genes, along with the chemokine receptor, Cxcr2 [17, 18].
Immunoblot analysis: Cellular protein was extracted from Cxcr2-bioengineered MSCs (with stable overexpression and/or silencing of CXCR2) and their respective controls with RIPA lysis buffer and subjected to 10% SDS-PAGE. The protein was then transferred to a polyvinylidene difluoride membrane. The membrane was incubated with primary antibodies against mouse-specific CXCR2, FLAG-Tag, and Myc-Tag, along β-Tubulin, and β-Actin as loading controls. Separately, Cxcr2-bioengineered MSCs with stable overexpression and/or silencing were treated with CXCL2, in the absence/presence of CXCR2 inhibitor, SB265620, and various signaling pathway inhibitors. The cellular protein was extracted after 48 h of treatment and subjected to SDS-PAGE as described earlier [19], and the membrane was incubated with primary antibodies against the signaling mediators p-Src, t-Src, p-Akt, t-Akt, p-ERK1/2, t-ERK1/2, p-STAT3, and t-STAT3.
Physiological assays
Proliferation assays
The proliferative potential of the bioengineered MSCs was evaluated using BrdU incorporation, colony formation, and MTT assays as described previously [16, 17]. Briefly, MSCs at 5 × 103 cells per well were seeded in a 96-well plate and incubated with/without transfection of transgenes for 48 h followed by treatment with increasing concentration of CXCL2 (BioLegend, San Diego, USA) (0–100 ng/ml) in absence or presence of CXCR2 inhibitor, SB265610 (Merck, Darmstadt, Germany) (0–100 µM) along with their respective controls as described previously [16].
BrdU incorporation assay: Post-treatment, MSCs were added with BrdU solutions (Roche, Basel, Switzerland) as mentioned in the manufacturer’s protocol. MSCs were fixed, permeabilized, and incubated with the anti-BrdU-Peroxidase antibody for 1h and the detection signal was developed by adding its substrate followed by measurement of absorbance at 370 nm with a reference wavelength at 490 nm as described previously [17].
Colony-Formation assay: The control, as well as transfected MSCs, was seeded at a density of 100 cells/well in a 6-well plate and incubated for 14 days along with different treatments followed by fixation and staining as described earlier [18]. The number of colonies displaying 5 or more cells was scored under an inverted microscope.
MTT assay: MSCs with stable overexpression and/or silencing of Cxcr2 were treated with CXCL2 (30 ng/ml), in the absence or presence of SB265620 (10 μM), and/or signaling pathway inhibitors PP2 (20 μM), Wortmannin (10 μM), PD98059 (30 μM), and S3I-201 (10 μM). After 48 h of incubation, the MTT assay was performed as described previously [18]. Separately, MSC,derived KLCs were treated with KGF (BioLegend, San Diego, USA) (10 ng/ml) in the absence or presence of Wortmannin (10 μM), and FAK14 (20 μM).
Migration assays
Boyden Chamber assay: Chemotaxis-mediated cell migration was evaluated using the Boyden chamber [17]. Briefly, Cxcr2-bioengineered MSCs (overexpressing Cxcr2) were plated at a density of 1×103 cells/well in the upper chamber Boyden chamber assembly and CXCL2 in the lower chamber as a chemoattractant. Separately, these MSCs were treated with CXCR2 inhibitor, SB265610 in the upper chamber as described previously [16].
Differentiation assays
Transdifferentiation of Cxcr2-bioengineered MSCs into keratinocyte-like cells (KLCs): Cxcr2-bioengineered MSC trans-differentiation in 2D culture: Cxcr2-bioengineered MSCs with stable overexpression and/or silencing were cultured for 14 days in a keratinocyte expansion medium containing keratinocyte growth supplement (HiMedia, Mumbai, India) for trans-differentiation into keratinocyte-like cells (KLCs). Post-trans-differentiation, KLCs were subjected to RNA isolation and immuno-cytochemical analysis to evaluate the differential expression of keratinocyte and epithelial markers.
Immunocytochemical analysis: Transdifferentiated KLCs were fixed using 4% paraformaldehyde, permeabilized with Triton X-100 followed by blocking with 1% BSA for 1 h. Subsequently, the cells were incubated overnight with primary antibodies against keratinocyte markers, Involucrin (IVL) and Cytokeratin 5 (CK5), keratinocyte growth factor receptor FGFR2IIIb and phospho-tyrosine (p-Tyr) followed by 45-minute incubation with Alexa Fluor 488/555-conjugated secondary antibodies. DAPI containing mounting medium was used for counterstaining the nuclei [17]. The images were captured using confocal microscopy (Olympus FV10i, Olympus).
Cxcr2-bioengineered MSC transdifferentiation in 3D culture: The 3D spheroid culture was performed by plating 104 Cxcr2-bioengineered MSCs with stable overexpression and/or silencing of Cxcr2 per well, in low attachment round bottom 96-well plate (Corning, USA). The 96-well plate was coated with type 1 collagen solution (3 mg/mL, Merck, Germany) before MSC seeding. After 24h, the medium was changed into keratinocyte expansion media (Himedia, India) for trans-differentiation of bioengineered MSC spheroids toward keratinocyte lineage. The cells were cultured for 14 days, bright-field microscope images were captured on days 3, 7, and 14, and the spheroid area was measured to evaluate the spheroid forming efficiency [20]. As described above, bioengineered MSCs were fixed for immuno-cytochemical analysis with the primary antibodies against CK14, Myc tag, IVL, and CK5, and RNA was isolated in a separate set of experiments to evaluate the gene expression of keratinocyte markers.
Generation of skin organoids
Stratified epithelium formation using Cxcr2-bioengineered MSC,derived KLCs: 3D skin organoids were generated in 24-well membrane inserts placed on a 24-well cell culture plate as mentioned previously [21]. NIH-3T3 cells were gently mixed in a 1:1 solution of type 1 collagen (3 mg/ml, Merck, Germany), and DMEM/F12 medium containing 5% FBS, 5 μg/mL insulin, and 10 ng/mL epidermal growth factor (EGF). The solution was transferred to the inserts and incubated for 30 min at room temperature. After confirming the gelation, 500 µL of the medium was added to the top of the insert and 1 mL to the bottom of the well. The matrix of fibroblasts and collagen was incubated at 37 °C with 5% CO2 for 7 days for the formation of a dermal equivalent. After 7 days, Cxcr2-bioengineered MSC,derived KLCs or control MSCGFP-derived KLCs were seeded onto each fibroblast layer and incubated at 37 °C with 5% CO2 for 30 min. 2 ml of low calcium epithelial medium (DMEM/F12 containing 4 mM L-glutamine, 10 μg/mL insulin, and 0.1% FBS) was added to the top of the insert and 3 mL to the bottom. Post 48 h of incubation, the medium was replaced with normal calcium medium (1.8 mM calcium chloride) and further incubated for 48 h. Subsequently, all the media were aspirated, and 3 mL of cornification medium (DMEM/F12 medium containing 4 mM L-glutamine, 10 μg/mL insulin, 2% FBS, and 1.8 mM calcium chloride) was added only to the bottom well to generate an air-liquid interface. The 3D skin organoid was maintained for 14 days at 37 °C with 5% CO2 and the medium was changed every other day. The 3D skin organoid was harvested by cutting the edge of the insert [21] and used for further gene and protein expression and organoid transplantation as skin graft studies. Keratinocyte-specific gene expression analysis was performed in the RNA isolated from the stratified skin organoids as described above. Separately, whole mounts of the generated 3D skin organoids were co-immunostained with Myc tag and CK5 antibodies, and separately with IVL and CK14 antibodies as described above.
In vivo studies
Generation of full excisional splinting wound healing model in Type 1 diabetes mice: Type 1 diabetes was generated in 6–8 weeks old, male, or female C57BL/6 mice by intraperitoneal administration of streptozotocin (STZ) at a dose of 70 mg/kg body weight for five consecutive days as described previously [16, 17]. Diabetes generation was confirmed by monitoring blood glucose levels at regular intervals for 2 weeks and intermittently till day 14 post-surgery. Excisional wounds were generated on the dorsal side using a 5 mm biopsy punch. Type 1 diabetic mice with two wounds on their dorsum were grouped separately and used for transplantation studies.
Cxcr2-bioengineered MSC transplantation therapy for skin regeneration in type 1 diabetes: Cxcr2-bioengineered MSCs with stable overexpression (MSCCxcr2) and/or silencing (MSCCxcr2 KD) along with their respective controls (MSCGFP and MSCScrKD) were transplanted intradermally onto the wound periphery (1 × 106 cells/wound). Doxycycline (2 mg/ml) was administered orally in the drinking water to the mice. A silicone splint to prevent healing by contraction, Tegaderm to prevent infection by covering the wound with transparent film, and adhesive bandage were used for dressing the wounds as described previously [16, 17, 22]. Morphometric wound healing analysis was performed by imaging while monitoring the mice on the 3rd, 5th, 7th, 10th, and 14th day post-surgery. The animals were euthanized after 14 days, and skin tissues were collected for further analysis. Morphometric wound healing analysis and histological analysis (hematoxylin–eosin, Sirius red staining) were performed to determine the rate of wound closure and tissue regeneration as described previously [17]. In vivo, engraftment and the fate of MSCs were evaluated using qPCR analysis and immunohistochemical analysis of the skin-specific keratinocyte and epithelial markers along with CXCR2 and Myc/GFP tag.
Immunohistochemical analysis: The microscopic slides containing skin tissue sections were deparaffinised with Xylene for 30 min and incubated in a gradient of ethanol (100–30% followed by distilled water, 5 min each). The slides were then incubated in antigen retrieval solution (1X citrate buffer and 0.05% Tween 20) at 90 °C for 15 min followed by blocking with goat serum for 1 h. The skin sections were co-immuno-stained with the primary antibodies against CXCR2/Myc tag, IVL/CK14, GFP/CXCR2, GFP/CK14, IVL/CXCR2, and α-SMA/CD31. Fluorescence intensity was determined using ImageJ software (ImageJ, NIH), and co-localization was calculated using Pearson’s correlation coefficient.
Skin organoid grafting on type 2 diabetic db/db transgenic mice: Skin organoids generated from Cxcr2-bioengineered MSC (MSCCxcr2)-derived KLCs or control MSCGFP-derived KLCs were transplanted onto the excisional splinting wounds in type 2 db/db transgenic male mice, 10–12 months old along with the controls (un-transplanted and collagen matrix without cells). Rate of wound closure, histological (hematoxylin–eosin and Sirius red staining), and immuno-histochemical (skin-specific keratinocyte, epithelial markers, and signaling mediators along with CXCR2 and Myc/GFP tag) analyses were performed to determine the skin tissue regeneration as mentioned previously [16, 17, 22].
Statistical analysis
All the experiments were performed at least thrice, and the data were represented as mean ± standard deviation of the mean (SD). Statistical significance was evaluated using one-way or two-way ANOVA followed by appropriate analysis such as post hoc or Tukey’s multiple comparison test or Student’s paired/un-paired t test (using GraphPad Prism 9.5.1). In immunofluorescence analysis, the correlation between two variables was analyzed using Pearson’s correlation coefficient. A P value of less than 0.05 was considered significant. Representative immunoblot images and photomicrographs from the experiments were reproduced at least thrice.
Results
Activation of the CXCL2/CXCR2 axis enhanced the proliferation and colony-forming efficiency of MSCs
Chemokine ligand–receptor interactions not only mediate the recruitment of cells but also their physiology. Our prior findings on the temporal expression analysis of an array of chemokines at the mice wound bed revealed a significant increase in the expression of the chemokine ligand CXCL2 post-surgery during the early to late stages of wound healing along with a concomitant increase in the expression of its cognate receptor CXCR2 in mouse bone marrow-derived MSCs [16]. This incited us to evaluate the effect of the CXCL2/CXCR2 axis in MSC physiology. A concentration-dependent increase in the MSC proliferation was observed in the presence of CXCL2 with a significant increase at 30 ng/ml (Fig. S1a). The CXCL2-induced proliferation was significantly abrogated in the presence of a pharmacological inhibitor of CXCR2, SB265610 (10 µM) as observed using BrdU incorporation (Fig. S1b) and colony-forming units (Fig. S1c) analyses indicating a plausible role of the CXCL2/CXCR2 axis in inducing the mitogenicity of MSCs. However, CXCL2 did not induce any significant change in the migration of MSCs even at higher concentrations indicating the specificity of the CXCL2/CXCR2 axis in inducing the proliferation but not migration of the MSCs (Fig. S1d). To further confirm these observations, MSCs were transiently transfected with either pCMV-EGFP (control) or pCMV-Cxcr2-MycDDK expression vectors, and overexpression was confirmed at mRNA (Fig. S2a-left panel) and protein levels (Fig. S2a-right panel). Cxcr2 overexpression significantly enhanced the colony-forming efficiency as compared to the control which was further potentiated in the presence of CXCL2 (30 ng/ml) (Fig. S2b). The CXCL2/CXCR2 axis-mediated increase in colony formation was significantly perturbed in the presence of SB265610 (10 µM) as well as other pathway blockers (Fig. S2b). Further, CXCL2 induced the proliferation of MSCs (BrdU incorporation) in both the control and Cxcr2 overexpressed groups were markedly abrogated by SB265610 (10 µM) as well as other pathway blockers (Fig. S2c, d). These observations confirmed the crucial role of the CXCL2/CXCR2 axis in mediating MSC proliferation.
CXCL2/CXCR2 axis induced MSC proliferation via the activation of STAT3/ERK1/2 signaling
To further evaluate the role of Cxcr2 in modulating MSC physiology, Cxcr2 was sub-cloned into a lentiviral vector to generate stable MSCs with Cxcr2 overexpression (MSCCxcr2) as described in Materials and Methods. MSCs were transduced with Cxcr2 overexpressing and/or silencing lentiviral particles followed by puromycin selection. Overexpression of Cxcr2 was confirmed by qPCR analysis (Fig. S3a) and immunoblotting with the tags FLAG and Myc, and CXCR2 (Fig. S3b). Similarly, the stable silencing of Cxcr2 in MSCs (MSCCxcr2 KD) was confirmed using qPCR analysis (Fig. S3c) and immunoblot analysis (Fig. S3d). MSCCxcr2 depicted a significant increase in the percent proliferation which was further increased in the presence of CXCL2 (Fig. S3e). MSCCxcr2 KD showed a significant decrease in the percent proliferation as compared to the control MSCScr (Fig. S3e). The CXCL2-mediated increase in proliferation in MSCCxcr2 was reverted in the presence of the CXCR2 inhibitor, SB265610, thereby confirming the role of Cxcr2 in regulating MSC proliferation (Fig. S3e). Further, stable Cxcr2 overexpression did not alter the migratory potential of MSCs (Fig. S3f). Next, to evaluate the molecular signaling pathway of Cxcr2-mediated increased MSC proliferation, MSCs with stable Cxcr2 overexpression and/or silencing along with their respective controls were treated with CXCL2 in the absence or presence of signaling pathway inhibitors and subjected to MTT proliferation assay. A significant increase in the percent proliferation was observed in the MSCCxcr2 group, which was reverted significantly in the presence of PP2 (a non-selective pan inhibitor of Src-family kinases), Wortmannin (a PI3K/AKT pathway inhibitor), PD98059 (ERK inhibitor), and S3I-201 (STAT3 inhibitor) (Fig. 1a). To confirm the specific signal transduction pathway of Cxcr2-mediated proliferation, immunoblot analysis was performed (Fig. 1b). Activation of ERK1/2 (phospho-ERK1/2) was observed in MSCCxcr2 in the presence of CXCL2 (30 ng/ml) (Figure 1b, left panel), which was abrogated by CXCR2 inhibitor, SB265610 (10 µM). Further, with Cxcr2 silencing a decreased expression of pERK1/2 was observed in the vehicle control group as well as in the presence of ERK inhibitor, PD98059 (30 µM) (Fig. 1b, right panel). Similarly, Cxcr2 overexpression also led to STAT3 activation, which was downregulated by STAT3 inhibitor, S3I-201 (30 µM) (Fig. 1b, left panel). Interestingly, MSCs with stable Cxcr2 silencing perturbed STAT3 activation in the presence of SB265610. (Fig. 1b, right panel). However, these MSCs with stable Cxcr2 modulation did not alter the Src and AKT levels. These observations suggested a plausible role of ERK1/2 and STAT3 signaling in the Cxcr2-mediated downstream targets in MSCs.
Activated STAT3 and ERK1/2 transcriptionally regulate the promoter activity of FGFR2IIIb in MSCCxcr2
Activated STAT3 and ERK1/2 [16] are known to translocate into the nucleus and act as transcriptional co-activators of target genes. Activated ERK1/2 in turn activates by phosphorylating SP1 and binding to the SP1 transcription factor-binding site (TFBS) on its target promoter [16]. MSCs possess the plasticity property that enables them to be transdifferentiated into non-obvious lineages like Keratinocytes [22], which are the major cell type present in the epidermal layer of the skin. Keratinocytes express the receptor FGFR2IIIb, also known as Keratinocyte Growth Factor Receptor (KGFR) which binds to its cognate ligand FGF7 or KGF. The FGF7/FGFR2IIIb signaling regulates the proliferation, migration, and differentiation of skin keratinocytes [23]. The in silico analysis of the promoter sequence of mouse FGFR2IIIb (KGFR) revealed the presence of four putative proximal SP1 (p-ERK1/2) binding sites (−6 to −91) (Fig. 1c) and one putative p-STAT3-binding site (−4163 to −4174) (Fig. 1d). Wild type (FGFR2IIIb SP1 (ERK1/2) WT, and FGFR2IIIb STAT3 WT), and deletion mutant constructs (ERK1/2 ΔBS4, ERK1/2 ΔBS4+3, ERK1/2 ΔBS4+3+2, ERK1/2 ΔBS4+3+2+1, and STAT3 ΔBS) of FGFR2IIIb luciferase reporter constructs were cloned as described in the Materials and Methods. MSCCxcr2 significantly induced the luciferase activity of the FGFR2IIIb SP1 (ERK1/2) WT (Fig. 1c), and FGFR2IIIb STAT3 WT (Fig. 1d) reporter constructs as compared with respective control. Further, deletion of the fourth SP1-binding sites (ERK1/2 ΔBS4) significantly reduced the luciferase activity (Fig. 1c). However, subsequent sequential deletion of the remaining three SP1-binding sites (ERK1/2 ΔBS3, ERK1/2 ΔBS2, ERK1/2 ΔBS1) did not alter the promoter activity to any further extent suggesting that BS4 is the essential site for p-ERK1/2-mediated SP1 binding on FGFR2IIIb promoter (Fig. 1c). Similarly, deletion of the p-STAT3-binding site (FGFR2IIIb STAT3 ΔBS) significantly reduced the promoter activity suggesting the role of STAT3 in regulating FGFR2IIIb (KGFR) transcription (Fig. 1d). Further, CXCL2 could significantly induce the activity of the WT ERK1/2 (Fig. 1e) and WT STAT3 (Fig. 1f) promoter in MSCCxcr2 but not in the control, MSCGFP, and MSCScr and the negative control, MSCCxcr2 KD groups. Additionally, the presence of CXCR2 inhibitor—SB265610, ERK1/2 inhibitor—PD98059, and STAT3 inhibitor—S3I-201 significantly reverted the CXCL2-mediated increase in the luciferase activity (Fig. 1e, f) in MSCCxcr2 suggesting a crucial role of activated ERK1/2 and STAT3 in MSC with stable Cxcr2 overexpression-mediated transcriptional regulation of FGFR2IIIb (KGFR). One limitation of the present study is that the luciferase promoter–reporter assay was performed by segregating the FGFR2IIIb promoter into two parts, one with only the SP1-binding sites without the STAT3-binding site, and the other with only the STAT3-binding site without the SP1-binding sites. Incorporating both SP1- and STAT3-binding sites together can provide a better understanding of the impact of sequential deletion in the context of the full promoter of FGFR2IIIb. Overall, these data indicate that Cxcr2 overexpression can potentiate the trans-differentiation of MSCs toward keratinocyte lineage.
Cxcr2 overexpression enhanced the trans-differentiation of MSCs toward keratinocyte-like cells
Next, we wanted to evaluate the role of Cxcr2 modulation in mediating the transdifferentiation of MSCs toward keratinocyte lineage. For transdifferentiation in 2D cell culture systems, Cxcr2-modulated MSCs and control MSCs were cultured in a complete keratinocyte expansion medium for 14 days as mentioned in the Materials and Methods. The expression of the keratinocyte markers (for primers refer to Table ST1) Basonuclin (Bnc1), cytokeratin 5 (Ck5), Ck14, Ck1, Involucrin (Ivl), and Stratifin (Sfn) was significantly increased in MSCCxcr2-keratinocyte-like cells (KLC) as compared with MSCGFP-KLCs when cultured in the keratinocyte growth-specific medium (Fig. 2a). Further, significantly enhanced expression of the epithelial markers E-Cadherin (Cdh1) and Mucin-1 (Muc1) in MSCCxcr2 suggesting the trans-differentiation of mesenchymal phenotype MSCs into epithelial phenotype KLCs (Fig. 2a). MSCs with stable Cxcr2 KD led to decreased expression of both keratinocytes and epithelial-specific gene expressions (Fig. 2a). Next, we evaluated the keratinocyte-specific protein markers in the Cxcr2-bioengineered MSCs using immunofluorescence analysis. We observed a marked increase in the fluorescence intensity of the CK5, CK14, and IVL in the MSCCxcr2-KLCs as compared with MSCGFP, MSCScr, and MSCCxcr2KD.KLCs (Fig. 2b). These observations indicate the positive role of Cxcr2 in increasing the trans-differentiation potential of MSCs toward KLCs.
KGF activates the cellular physiology of transdifferentiated MSCCxcr2-KLCs
FGFR2IIIb is a receptor tyrosine kinase that gets activated upon KGF binding and mediates the proliferation, migration, and differentiation of epithelial cells during wound healing. Immunofluorescence analysis of these Cxcr2-modulated MSC,derived KLCs in the absence or presence of KGF (10 ng/ml) revealed a marked increase in the co-localization of FGFR2IIIb (KGFR) and p-Tyr in the MSCCxcr2 group in the presence of KGF (Fig. S4a, arrow-head denoting co-localization) as compared with the control, MSCGFP-KLCs. Further, MSCCxcr2 KD-KLCs did not show any significant change in the co-localization of FGFR2IIIb, and p-Tyr as compared to MSCScr-KLCs. Additionally, the presence of KGF did not alter the Pearson’s correlation coefficient in the MSCScr and MSCCxcr2KD-KLCs (Fig. S4a). This indicates the activation of FGFR2IIIb only in the MSCCxcr2-KLCs that in turn may induce the physiological phenotype in these cells. Next, we performed proliferation and migration assays of KLCs treated with KGF (FGF7) in the absence or presence of pharmacological inhibitors of the signaling pathway. The percent proliferation of MSCCxcr2 -KLCs increased significantly in the presence of KGF (10 ng/ml) that was reverted significantly in the presence of signaling pathway inhibitors of AKT (Wortmannin, 10 µM), but not FAK (FAK14, 20 µM) (Fig. S4b). Furthermore, we observed a KGF-induced significant increase in the number of cells migrated in the MSCGFP-KLC and MSCCxcr2-KLC groups that were reverted significantly in the presence of both AKT and FAK inhibitors (Fig. S4c). Further, Cxcr2 silencing did not alter the migration of the MSCGFP-KLC and MSCCxcr2-KLC groups (Fig. S4c). These results confirm the keratinocyte-specific cellular phenotype of MSCCxcr2-derived KLCs.
Cxcr2 overexpression increased the 3D spheroid forming efficiency during the transdifferentiation of MSCs toward keratinocyte-like cells
One of the main properties of stem/progenitor cells is to self-organize into spheroid-like structures that can partially mimic the physiological functions of the tissue [20]. Subsequently, we wanted to evaluate the effect of Cxcr2 modulation in MSCs undergoing keratinocyte trans-differentiation in 3D spheroid culture conditions. In the present study, stable Cxcr2-modulated MSCs were cultured in low adhesion plates to form spheroids as mentioned in the Materials and Methods. The size of the spheroids increased significantly from day 4 to day 14 in the MSCCxcr2 cultured in keratinocyte expansion medium as compared with the controls (MSCGFP, MSCScr) and negative control (MSCCxcr2 KD) groups indicating enhanced spheroid forming efficiency of MSCCxcr2 (Fig. 3a). Quantification of the 3D spheroids generated by MSCCxcr2 groups cultured in keratinocyte expansion medium depicted significantly large-sized spheroids at day 14 as compared with their controls as well as those cultured in MSC expansion medium (Fig. 3b). Morphologically, the spheroids in the MSCCxcr2 group demonstrated a proliferating layer of cells surrounding the core of the spheroid (Fig. 3a) correlating with the characteristics of epithelial spheroids which demonstrate a stromal core and an underlying surface-anchored keratinocyte layer [20]. Further, qPCR analysis of the keratinocyte and epithelial markers in the spheroids revealed a significant increase in the expression of the keratinocyte markers—Ck5, Ck14, Ck13, Ck1, Ivl, and Sfn (Fig. 3c). A significant decrease in the expression of Ck13, Ck1, and Sfn was observed with Cxcr2 silencing. Immunofluorescence analysis depicted a marked increase in the expression of the keratinocyte markers CK14 along with Myc tag (Fig. 3d), and Involucrin, and CK5 (Fig. 3e) in MSCCxcr2-KLC spheroids. These observations further confirm the trans-differentiation of MSCs toward KLCs and suggest the in vivo therapeutic potential of MSCCxcr2 in enhancing tissue regeneration.
Transplantation of MSCCxcr2 accelerated wound closure and potentiated re-epithelialization at the wound bed in type 1 diabetic mouse model
To evaluate the in vivo therapeutic potential of MSCCxcr2, a full-thickness excisional splint wound healing model was generated in streptozotocin-induced type 1 diabetic mouse that was confirmed by the blood glucose levels (Fig. 4a). The type 1 diabetic mouse was transplanted intradermally at the wound periphery with 1 × 106 cells/wound of MSC with stable Cxcr2 overexpression and/or silencing groups as well as their respective controls. Morphometric wound healing analysis of the regenerated wound was performed which depicted markedly reduced wound size (Fig. 4b) as well as a significantly higher rate of wound closure (Fig. 4c) in the MSCCxcr2 transplanted (Tx) group as compared with the MSCGFP and/or MSCScr (controls) and MSCCxcr2 KD (negative control) Tx groups. This was further corroborated by hematoxylin–eosin (Fig. 4d, e) and Sirius red (Fig. 4f, g) staining for histological analysis of the regenerated wounds, which depicted the thickening of the epidermis layer (Fig 4d, S5), higher granulation tissue formation, and increased collagen deposition in the MSCCxcr2 group (Fig. 4d-g). Also, the data suggest a higher number of H&E-stained infiltrated cells at the wound site of the MSCCxcr2 Tx group as compared with the MSCGFP and/or MSCScr (controls), and MSCCxcr2 KD (negative control) Tx groups indicating Cxcr2-mediated accelerated wound tissue regeneration (Fig. S5).
MSCCxcr2 transplantation increased the expression of keratinocyte and epithelial-specific markers at type 1 diabetic wound bed
For evaluation of the epithelial- and keratinocyte-specific gene expression, qPCR analysis was performed with the regenerated skin tissues post-surgery day 7 (Fig. S6a-c) and day 14 (Fig. S7a-c). The expression of the epithelial markers Cdh1 and Muc1 increased significantly in MSCCxcr2 transplanted group as compared with the un-Tx and MSCGFP Tx group at day 7 (Fig S6b), whereas at day 14, a significant increase in the expression of the basal keratinocyte-specific markers Bnc1, Ck5, Ck14, intermediate markers Ck13 and Ck10, and terminal differentiation markers Ivl, Sfn, and Flg was observed in the MSCCxcr2 transplanted group as compared with the un-Tx group or differentially with the MSCGFP Tx group (Fig. S7a). The MSCCxcr2 Tx group also demonstrated a significant increase in the epithelial-specific markers EpCAM, Cdh1, Claudin (Cldn1), and Muc1 as compared with un-Tx and MSCGFP Tx groups (Fig. S7b). Further, a significant increase in the MSC markers CD73, CD90.2, and CD105 expression was observed on day 7 (Fig. S6c) but only CD73 was significantly expressed at day 14 in the MSCCxcr2 Tx group (Fig. S7c) suggesting MSCCxcr2-mediated accelerated wound tissue regeneration was occurring by accelerating the fate of the transplanted cells toward keratinocytes at the wound bed of type 1 diabetic mouse. For evaluation of the engraftment and fate of the transplanted cells, co-immunostaining of CXCR2 and Myc tag was performed which depicted a higher co-localization in the MSCCxcr2 Tx group as compared with the MSCGFP or MSCScr (controls) and MSCCxcr2 KD (negative control) Tx groups (Fig. 5a) and quantification of co-localization (Fig. 5b). Since our control and negative control groups were GFP tagged while the MSCCxcr2 lacks the GFP tag instead expressed Myc tag, we stained these sections with GFP and CXCR2. We observed an increased immunofluorescence intensity of GFP staining in the MSCGFP or MSCScr (controls) and MSCCxcr2 KD (negative control) Tx groups while the MSCCxcr2 Tx group depicted higher immunofluorescence intensity of CXCR2 as compared with the others (Fig. S8a, b). Further, the co-immunostaining of the keratinocyte markers Involucrin (IVL) and CK14 also depicted higher co-localization in the MSCCxcr2 Tx group (Fig. 5c, d) suggesting enhanced re-epithelialization-mediated repair and regeneration of type 1 diabetic wound tissue. Similarly, immunostaining with GFP and CK14 revealed a higher immunofluorescence intensity of GFP in the control and negative control MSC Tx groups while the immunofluorescence intensity of CK14 was markedly higher in the MSCCxcr2 Tx group (Fig. S8c, d). Additionally, co-immunostaining of CXCR2 with the keratinocyte-specific marker Involucrin depicted higher co-localization in the MSCCxcr2 Tx group as compared with controls (Fig. S9a) and quantification of colocalization (Fig. S9b). Although the expression of α-SMA was found to be significantly higher in all the transplanted groups, the CD31 expression was not altered as compared to the un-transplanted group, indicating less blood vessel formation in the regenerated tissue (Fig. S9c,d). This incited us to generate 3D skin organoids containing the stratified epidermal and dermal layers.
MSCCxcr2-KLC,derived skin organoid grafting enhanced skin tissue regeneration in type 2 diabetic (db/db) transgenic mice wounds
The conventional 2D cell culture often fails to represent the structural and physiological properties of a complex structure like skin. Therefore, 3D culture systems are warranted for depicting the pathophysiology of various skin diseases and to generate skin equivalents [24, 25] that can be used for grafting/transplantation in chronic non-healing wounds. This led us to evaluate the efficiency of MSCCxcr2.KLC to form stratified 3D skin organoids. The MSCCxcr2.KLC or the MSCGFP.KLC (control) was seeded onto the fibroblast-derived dermal equivalent as described in the flow chart (Fig. 6a) and Materials and Methods. A marked increase in the expression of the keratinocyte markers—Ck1, Ck13, and Sfn, and the epithelial markers—Cdh1 and Muc1 was observed in the MSCCxcr2-KLC organoids as compared with the MSCGFP-KLC organoids (Fig. 6b). Further, the organoid whole mounts were subjected to H&E staining to determine the morphology (Fig. 6c), and co-immuno-stained with Myc tag and CK5 (Fig. 6d, upper panel), and Involucrin and CK14 (Fig. 6d, lower panel) A significantly increased expression, represented by the increased fluorescence intensity of the markers, was observed in MSCCxcr2-KLC organoids as compared to the MSCGFP-KLC organoids (Fig. 6d, e). Next, these skin organoids were grafted in the chronic excisional splinting wound model generated in type 2 diabetic (db/db) transgenic old mice which correlates well with the occurrence of DFU in patients with diabetes mellitus at an advanced age [26]. Michaels et al. demonstrated significant impairment in vascularity, cellular proliferation, and granulation tissue formation at the wound bed of db/db transgenic mice representing type 2 diabetes as compared with the STZ-induced mice model of type 1 diabetes leading to delayed wound healing in the former than later [27]. Interestingly, the percent wound closure observed in the present study in the un-transplanted group (Un-Tx) in db/db mice was less (6.9%) (Fig. 7a, b) as compared to the Un-Tx group in the type1 diabetic model (12.6%) (Fig. 4b, c) indicating the severity of type 2 diabetic wounds. Morphometric wound healing analysis depicted a marked decrease in wound size (Fig. 7a) and a significant increase in the percent wound closure in the MSCCxcr2-KLC organoid grafted group as compared with the Un-Tx, empty collagen grafted, and MSCGFP-KLC organoid grafted groups (Fig. 7b). Although we observed a significant increase in the control MSCGFP-KLC organoid grafted group (41.1% wound healing) as compared with the other control groups (Un-Tx and empty collagen grafted groups), however, it was less effective as compared with the MSCCxcr2-KLC organoid grafted group which showed \(\sim\) 71% wound healing (Fig. 7a, b). These results were supported by histological analysis of the hematoxylin–eosin-stained skin tissue sections which depicted increased re-epithelialization and thickness of the epidermis along with Sirius red staining depicting increased collagen deposition in the MSCCxcr2-KLC organoid grafted group (Fig. 7c, d). Additionally, immunofluorescence analysis revealed a significantly higher co-localization of CXCR2 with the Myc tag in the MSCCxcr2-KLC organoid grafted group as compared with the MSCGFP-KLC organoid grafted group (Fig. S10a, b). Similarly, immunostaining with GFP and CXCR2 revealed a higher immunofluorescence intensity of GFP in the MSCGFP-KLC organoid grafted group and CXCR2 in the MSCCxcr2-KLC organoid grafted group (Fig. S10c,d). Immunofluorescence analysis revealed a marked increase in the expression of pERK1/2 (Fig. S11a) and pSTAT3 (Fig. S11b) in the MSCCxcr2-KLC,derived 3D skin organoid grafted group. Further, increased co-localization of Myc/pERK1/2 (Fig. S11c) and Myc/pSTAT3 (Fig. S11d) was also observed in the regenerated tissue sections of MSCCxcr2-KLC organoid grafted group suggesting the activation of ERK1/2 and STAT3 signaling pathways. Next, co-immunostaining of the Myc tag with the keratinocyte markers CK5 (Fig. 8a, b) and Involucrin (Fig. S12a, b) also depicted higher co-localization in the MSCCxcr2-KLC organoid grafted group further confirming accelerated chronic type 2 diabetic wound tissue regeneration by re-epithelialization. Similarly, immunostaining with GFP and CK5 (Fig. S13a, b) and GFP and IVL (Fig. S13c, d) revealed a higher immunofluorescence intensity of GFP in the MSCGFP-KLC organoid grafted group and CK5 and IVL in the MSCCxcr2-KLC organoid grafted group (Fig. S13c, d). Further, co-immunostaining of α-SMA and CD31 (Fig. 8c, d) depicted a higher expression in the dermal layer of both the MSCCxcr2-KLC organoid and MSCGFP-KLC organoid grafted groups indicating enhanced vascularity or endothelialization-mediated skin tissue regeneration in type 2 diabetic wound bed. Fibroblasts secrete several angiogenic growth factors, such as VEGF, TGF-β, and PDGF, which support the formation of endothelial cell lumen and endothelial cell sprouting [28]. Since we plated an equal number of fibroblasts in the dermal equivalent of the organoid, we achieved an equal extent of vascularization in both the groups but enhanced re-epithelialization as well as re-endothelialization-mediated skin tissue regeneration in the MSCCxcr2-KLC organoid grafted group.
Discussion
The complex process of wound healing is severely disrupted due to the pathological abnormalities associated with chronic diseases like diabetes. Diabetic foot ulcers demonstrate altered expression of chemokines, cytokines, and growth factors that regulate the process of wound healing [6,7,8]. Among the stem cell therapies, MSC transplantation in diabetic wound healing has shown promising results. However, low engraftment, survivability, proliferation, and differentiation of the transplanted MSCs are challenging problems that limit their clinical translation [13,14,15]. This necessitates developing bioengineered MSCs that enhance their engraftment, and trans-differentiation upon transplantation in the chronic wound microenvironment. MSCs express a wide repertoire of chemokine receptors that modulate their physiological responses in the presence of their cognate ligands [12]. The chemokine ligand/receptor axis-based gene therapy approach has been widely used to accelerate wound closure. Our previous study reported an enhanced migration of the intravenously transplanted Cxcr6 bioengineered MSCs in response to the increased level of its cognate ligand CXCL16 at the wound area [16]. The overexpression of Cxcr4, a potent angiogenic factor, also enhanced the migration of MSCs and angiogenesis at the injury site via its cognate ligand CXCL12 [29]. Similarly, CCR2 overexpressed MSCs exhibited increased homing toward the injury site in response to the increased level of CCL2 in diabetic db/db mice wounds [10]. In this line, we have observed a significant increase in the expression of the CXCR2 cognate ligand CXCL2 in type 1 and type 2 diabetic wounds as compared with control non-wounded skin (Fig. S14). CXCR2 has been known to promote the recruitment of neutrophils at the site of inflammation and facilitate wound healing and angiogenesis. In the present study, we demonstrated the role of the chemokine receptor CXCR2 in regulating MSC physiology. Recently, Cxcr2 overexpression in MSCs has also been demonstrated to improve the migration and homing of the cells toward the site of injury in response to the ligands CXCL2 and CXCL5 [30, 31]. However, we did not observe any significant change in MSC migration with Cxcr2 overexpression in the absence or presence of the ligand CXCL2. Interestingly, the observed increase in proliferation of MSCs with Cxcr2 overexpression in our study correlates well with the recent study by Shen et al. which demonstrated an enhanced survival rate of the Cxcr2 overexpressed MSCs both in vitro and in vivo [31]. Our study further revealed the role of pSTAT3 and pERK1/2 in regulating CXCR2.mediated transcriptional regulation of the downstream target, FGFR2IIIb. ERK1/2 has been known to be a major downstream effector in CXCR2-mediated signal transduction [31, 32]. FGFR2IIIb, also known as FGFR2b or KGFR has been reported to regulate the early differentiation of normal human keratinocytes [33].
Re-epithelialization is a crucial process regulated by keratinocytes in which the dermal and mucosal wound surface is covered, and the epidermal barrier is restored. Several studies have reported impaired keratinocyte proliferation and migration in diabetic patients [34, 35] as well as in diabetic animal models [36, 37]. In the present study, we demonstrated the role of CXCR2 in enhancing the transdifferentiation of MSCs toward keratinocyte-like cells. Subsequently, KGF-induced enhanced proliferation and migration of MSCCxcr2-KLCs correlated well with prior studies demonstrating KGF-mediated enhanced proliferation and migration of keratinocytes [38]. Interestingly, Guo et al. reported no significant change in the rate of wound healing in KGF knockout mice as compared to control [39]. However, a more recent study by the same group reported a significantly delayed wound closure rate in diabetic mice in the absence of KGF (FGF7) as compared to the non-diabetic group, highlighting the importance of KGF/FGFR2IIIb signaling in accelerating wound closure and re-epithelialization in diabetic mice [40]. Furthermore, delayed or impaired wound healing was reported in CXCR2 deficient mice due to the lack of neutrophil and monocyte recruitment and reduced secretion of IL-1β at the wound site [41, 42]. Corroborating with these observations, our study demonstrated enhanced re-epithelialization-mediated skin tissue regeneration in murine diabetic wounds upon transplantation of Cxcr2-bioengineered MSCs. The higher engraftment of MSCCxcr2 at the diabetic wound bed in our preclinical study as well as others was in part due to an increased expression of its cognate ligand CXCL2 in diabetic conditions [43]. Our observations correlated well with a study by Kroeze et al., which identified CXCR2 along with four other chemokine receptors CCR1, CCR10, CXCR1, and CXCR3 to be involved in the autocrine regulation of re-epithelialization [44].
Skin is a structurally complex organ performing multiple functions and mimicking the morphological and physiological properties of skin that require 3D culture systems which resemble the in vivo systems. This led us to generate a 3D organotypic spheroid culture for the transdifferentiation of these bioengineered MSCs. Recent studies have focused on generating functional epidermal spheroids that demonstrate vasculogenic properties and the growth of skin appendages like hair follicles [20, 45]. Furthermore, we utilized air–liquid interface culture in our study settings to generate a 3D stratified skin organoid as reported earlier by layered co-culture of fibroblasts and keratinocytes that successfully generates 3D stratified skin structures [21, 45, 46]. We generated the dermal equivalent by seeding NIH3T3 cells in a collagen scaffold and subsequently seeded the bioengineered MSC,derived KLCs on the dermal equivalent. Diabetic foot ulcers are not only more prevalent among older patients with type 2 diabetes but also the vascularity is poor in the lower extremities of type 2 diabetic patients which leads to non-healing wounds [47]. Grafting of the Cxcr2-bioengineered MSC,derived KLC skin organoids at the chronic wounds in old (50–52 weeks old) transgenic db/db mice in the present study resulted in an enhanced re-epithelialization at the epidermal layer by the transdifferentiated KLCs as well as vascularity evidenced by increased staining of CD31 at the dermal layer.
In conclusion, we demonstrated the role of the chemokine receptor Cxcr2 in enhancing the transdifferentiation potential of MSCs toward keratinocyte-like cells via transcriptional upregulation of FGFR2IIIb. These bioengineered MSCCxcr2. KLC, derived skin organoids upon grafting onto chronic diabetic wounds potentiated the healing by skin regeneration. Our study demonstrates a platform technology for chronic diabetic wound healing (diabetic foot ulcers) with allogenic MSC,derived skin organoid grafts.
Data availability
All the data generated have been included in the manuscript and supplemental data available online.
References
Aitcheson SM, Frentiu FD, Hurn SE, Edwards K, Murray RZ (2021) Skin wound healing: normal macrophage function and macrophage dysfunction in diabetic wounds. Molecules 26(16):4917. https://doi.org/10.3390/molecules26164917
Yang S, Xu M, Meng G, Lu Y (2020) SIRT3 deficiency delays diabetic skin wound healing via oxidative stress and necroptosis enhancement. J Cell Mol Med 24(8):4415–4427. https://doi.org/10.1111/jcmm.15100
Furue K, Ulzii D, Tanaka Y, Ito T, Tsuji G, Kido-Nakahara M, Nakahara T, Furue M (2020) Pathogenic implication of epidermal scratch injury in psoriasis and atopic dermatitis. J Dermatol 47(9):979–988. https://doi.org/10.1111/1346-8138.15507
Bieber T (2022) Atopic dermatitis: an expanding therapeutic pipeline for a complex disease. Nat Rev Drug Discov 21(1):21–40. https://doi.org/10.1038/s41573-021-00266-6
Yao D, Ye S, He Z, Huang Y, Deng J, Wen Z, Chen X, Li H, Han Q, Deng H, Zhao RC (2021) Adipose-derived mesenchymal stem cells (AD-MSCs) in the treatment for psoriasis: results of a single-arm pilot trial. Ann Transl Med 9(22):1653. https://doi.org/10.21037/atm-21-5028
McDermott K, Fang M, Boulton AJ, Selvin E, Hicks CW (2023) Etiology, epidemiology, and disparities in the burden of diabetic foot ulcers. Diabetes Care 46(1):209–221. https://doi.org/10.2337/dci22-0043
Patel S, Srivastava S, Singh MR, Singh D (2019) Mechanistic insight into diabetic wounds: pathogenesis, molecular targets and treatment strategies to pace wound healing. Biomed Pharmacother 112:108615. https://doi.org/10.1016/j.biopha.2019.108615
Fang WC, Lan CC (2023) The epidermal keratinocyte as a therapeutic target for management of diabetic wounds. Int J Mol Sci 24(5):4290. https://doi.org/10.3390/ijms24054290
Barros JF, Waclawiak I, Pecli C, Borges PA, Georgii JL, Ramos-Junior ES, Canetti C, Courau T, Klatzmann D, Kunkel SL, Penido C, Canto FB, Benjamim Claudia F (2019) Role of chemokine receptor CCR4 and regulatory T cells in wound healing of diabetic mice. J Investig Dermatol 139(5):1161–1170. https://doi.org/10.1016/j.jid.2018.10.039
Kuang S, He F, Liu G, Sun X, Dai J, Chi A, Tang Y, Li Z, Gao Y, Deng C, Lin Z (2021) CCR2-engineered mesenchymal stromal cells accelerate diabetic wound healing by restoring immunological homeostasis. Biomaterials 275:120963. https://doi.org/10.1016/j.biomaterials.2021.120963
Xu J, Hu J, Idlett-Ali S, Zhang L, Caples K, Peddibhotla S, Reeves M, Zgheib C, Malany S, Liechty KW (2022) Discovery of small molecule activators of chemokine receptor CXCR4 that improve diabetic wound healing. Int J Mol Sci 23(4):2196. https://doi.org/10.3390/ijms23042196
Cuesta-Gomez N, Graham GJ, Campbell JD (2021) Chemokines and their receptors: predictors of the therapeutic potential of mesenchymal stromal cells. J Transl Med 19(1):1–10. https://doi.org/10.1186/s12967-021-02822-5
Jo H, Brito S, Kwak BM, Park S, Lee MG, Bin BH (2021) Applications of mesenchymal stem cells in skin regeneration and rejuvenation. Int J Mol Sci 22(5):2410. https://doi.org/10.3390/ijms22052410
Cho J, D’Antuono M, Glicksman M, Wang J, Jonklaas J (2018) A review of clinical trials: mesenchymal stem cell transplant therapy in type 1 and type 2 diabetes mellitus. Am J Stem Cells 7(4):82
Bhansali S, Dutta P, Kumar V, Yadav MK, Jain A, Mudaliar S, Bhansali S, Sharma RR, Jha V, Marwaha N, Khandelwal N (2017) Efficacy of autologous bone marrow-derived mesenchymal stem cell and mononuclear cell transplantation in type 2 diabetes mellitus: a randomized, placebo-controlled comparative study. Stem Cells Develop 26(7):471–481. https://doi.org/10.1089/scd.2016.0275
Dhoke NR, Kaushik K, Das A (2020) Cxcr6-based mesenchymal stem cell gene therapy potentiates skin regeneration in murine diabetic wounds. Mol Ther 28(5):1314–1326. https://doi.org/10.1016/j.ymthe.2020.02.014
Kaushik K, Das A (2020) TWIST1-reprogrammed endothelial cell transplantation potentiates neovascularization-mediated diabetic wound tissue regeneration. Diabetes 69(6):1232–1247. https://doi.org/10.2337/db20-0138
Dhoke NR, Kalabathula E, Kaushik K, Geesala R, Sravani B, Das A (2016) Histone deacetylases differentially regulate the proliferative phenotype of mouse bone marrow stromal and hematopoietic stem/progenitor cells. Stem Cell Res 17(1):170–180. https://doi.org/10.1016/j.scr.2016.07.001
Kaushik K, Das A (2019) Cycloxygenase-2 inhibition potentiates trans-differentiation of Wharton’s jelly–mesenchymal stromal cells into endothelial cells: transplantation enhances neovascularization-mediated wound repair. Cytotherapy 21(2):260–273. https://doi.org/10.1016/j.jcyt.2019.01.004
Ebner-Peking P, Krisch L, Wolf M, Hochmann S, Hoog A, Vári B, Muigg K, Poupardin R, Scharler C, Schmidhuber S, Russe E (2021) Self-assembly of differentiated progenitor cells facilitates spheroid human skin organoid formation and planar skin regeneration. Theranostics 11(17):8430. https://doi.org/10.7150/thno.59661
Kim Y, Ju JH (2019) Generation of 3D skin organoid from cord blood-derived induced pluripotent stem cells. J Vis Exp 146:e59297. https://doi.org/10.3791/59297
Geesala R, Bar N, Dhoke NR, Basak P, Das A (2016) Porous polymer scaffold for on-site delivery of stem cells—protects from oxidative stress and potentiates wound tissue repair. Biomaterials 77:1–3. https://doi.org/10.1016/j.biomaterials.2015.11.003
Amidzadeh Z, Yasami-Khiabani S, Rahimi H, Bonakdar S, Shams D, Habibi-Anbouhi M, Golkar M, Shokrgozar MA (2022) Enhancement of keratinocyte growth factor potential in inducing adipose-derived stem cells differentiation into keratinocytes by collagen-targeting. J Cell Mol Med 26(23):5929–5942. https://doi.org/10.1111/jcmm.17619
Kim Y, Park N, Rim YA, Nam Y, Jung H, Lee K, Ju JH (2018) Establishment of a complex skin structure via layered co-culture of keratinocytes and fibroblasts derived from induced pluripotent stem cells. Stem Cell Res Ther 9:1. https://doi.org/10.1186/s13287-018-0958-2
Wang X, Wang S, Guo B, Su Y, Tan Z, Chang M, Diao J, Zhao Y, Wang Y (2021) Human primary epidermal organoids enable modeling of dermatophyte infections. Cell Death Dis 12(1):35. https://doi.org/10.1038/s41419-020-03330-y
Jalilian M, Sarbarzeh PA, Oubari S (2020) Factors related to severity of diabetic foot ulcer: a systematic review. Diabet Metabol Syndrome Obes 13:1835. https://doi.org/10.2147/DMSO.S256243
Michaels J, Churgin SS, Blechman KM, Greives MR, Aarabi S, Galiano RD, Gurtner GC (2007) db/db mice exhibit severe wound-healing impairments compared with other murine diabetic strains in a silicone-splinted excisional wound model. Wound Repair Regen 15(5):665–670. https://doi.org/10.1111/j.1524-475X.2007.00273.x
Newman AC, Nakatsu MN, Chou W, Gershon PD, Hughes CC (2011) The requirement for fibroblasts in angiogenesis: fibroblast-derived matrix proteins are essential for endothelial cell lumen formation. Mol Biol Cell 22(20):3791–3800. https://doi.org/10.1091/mbc.e11-05-0393
Han SH, Chae DS, Kim SW (2022) Dual CXCR4/IL-10 gene-edited human amniotic mesenchymal stem cells exhibit robust therapeutic properties in chronic wound healing. Int J Mol Sci 23(23):15338. https://doi.org/10.3390/ijms232315338
Li Q, Lian Y, Deng Y, Chen J, Wu T, Lai X, Zheng B, Qiu C, Peng Y, Li W, Xiang AP (2021) mRNA-engineered mesenchymal stromal cells expressing CXCR2 enhances cell migration and improves recovery in IBD. Mol Therapy Nucleic Acids 26:222–236. https://doi.org/10.1016/j.omtn.2021.07.009
Shen Z, Wang J, Huang Q, Shi Y, Wei Z, Zhang X, Qiu Y, Zhang M, Wang Y, Qin W, Huang S (2018) Genetic modification to induce CXCR2 overexpression in mesenchymal stem cells enhances treatment benefits in radiation-induced oral mucositis. Cell Death Dis 9(2):229. https://doi.org/10.1038/s41419-018-0310-x
Gavard J, Hou X, Qu Y, Masedunskas A, Martin D, Weigert R, Li X, Gutkind JS (2009) A role for a CXCR2/phosphatidylinositol 3-kinase γ signaling axis in acute and chronic vascular permeability. Mol Cell Biol 29(9):2469–2480. https://doi.org/10.1128/MCB.01304-08
Rosato B, Ranieri D, Nanni M, Torrisi MR, Belleudi F (2018) Role of FGFR2b expression and signaling in keratinocyte differentiation: Sequential involvement of PKCδ and PKCα. Cell Death Dis 9(5):565. https://doi.org/10.1038/s41419-018-0509-x
Lan CC, Liu IH, Fang AH, Wen CH, Wu CS (2008) Hyperglycaemic conditions decrease cultured keratinocyte mobility: implications for impaired wound healing in patients with diabetes. Br J Dermatol 159(5):1103–1115. https://doi.org/10.1111/j.1365-2133.2008.08789.x
Spravchikov N, Sizyakov G, Gartsbein M, Accili D, Tennenbaum T, Wertheimer E (2001) Glucose effects on skin keratinocytes: implications for diabetes skin complications. Diabetes 50(7):1627–1635. https://doi.org/10.2337/diabetes.50.7.1627
Sakai S, Endo Y, Ozawa N, Sugawara T, Kusaka A, Sayo T, Inoue S, Tagami H (2003) Characteristics of the epidermis and stratum corneum of hairless mice with experimentally induced diabetes mellitus. J Investig Dermatol 120(1):79–85. https://doi.org/10.1046/j.1523-1747.2003.12006.x
Werner S, Breeden M, Hübner G, Greenhalgh DG, Longaker MT (1994) Induction of keratinocyte growth factor expression is reduced and delayed during wound healing in the genetically diabetic mouse. J Investig Dermatol 103(4):469–473. https://doi.org/10.1111/1523-1747.ep12395564
Denzinger M, Link A, Kurz J, Krauss S, Thoma R, Schlensak C, Wendel HP, Krajewski S (2018) Keratinocyte growth factor modified messenger RNA accelerating cell proliferation and migration of keratinocytes. Nucleic Acid Ther 28(6):335–347. https://doi.org/10.1089/nat.2018.0737
Guo L, Degenstein L, Fuchs E (1996) Keratinocyte growth factor is required for hair development but not for wound healing. Genes Dev 10(2):165–175. https://doi.org/10.1101/gad.10.2.165
Peng C, Chen B, Kao HK, Murphy G, Orgill DP, Guo L (2011) Lack of FGF-7 further delays cutaneous wound healing in diabetic mice. Plast Reconstr Surg 128(6):673e–684e. https://doi.org/10.1097/PRS.0b013e318230c521
Devalaraja RM, Nanney LB, Qian Q, Du J, Yu Y, Devalaraja MN, Richmond A (2000) Delayed wound healing in CXCR2 knockout mice. J Investig Dermatol 115(2):234–244. https://doi.org/10.1046/j.1523-1747.2000.00034.x
Milatovic S, Nanney LB, Yu Y, White JR, Richmond A (2003) Impaired healing of nitrogen mustard wounds in CXCR2 null mice. Wound Repair Regener 11(3):213–219. https://doi.org/10.1046/j.1524-475X.2003.11310.x
Wetzler C, Kämpfer H, Stallmeyer B, Pfeilschifter J, Frank S (2000) Large and sustained induction of chemokines during impaired wound healing in the genetically diabetic mouse: prolonged persistence of neutrophils and macrophages during the late phase of repair. J Investig Dermatol 115(2):245–253. https://doi.org/10.1046/j.1523-1747.2000.00029.x
Kroeze KL, Boink MA, Sampat-Sardjoepersad SC, Waaijman T, Scheper RJ, Gibbs S (2012) Autocrine regulation of re-epithelialization after wounding by chemokine receptors CCR1, CCR10, CXCR1, CXCR2, and CXCR3. J Investig Dermatol 132(1):216–225. https://doi.org/10.1038/jid.2011.245
Lei M, Schumacher LJ, Lai YC, Juan WT, Yeh CY, Wu P, Jiang TX, Baker RE, Widelitz RB, Yang L, Chuong CM (2017) Self-organization process in newborn skin organoid formation inspires strategy to restore hair regeneration of adult cells. Proc Natl Acad Sci 114(34):E7101–E7110. https://doi.org/10.1073/pnas.1700475114
Murakami M, Akagi T, Sasano Y, Akashi M (2021) Effect of 3D-fibroblast dermis constructed by layer-by-layer cell coating technique on tight junction formation and function in full-thickness skin equivalent. ACS Biomater Sci Eng 7(8):3835–3844. https://doi.org/10.1021/acsbiomaterials.1c00375
Megallaa MH, Ismail AA, Zeitoun MH, Khalifa MS (2019) Association of diabetic foot ulcers with chronic vascular diabetic complications in patients with type 2 diabetes. Diabetes Metab Syndr 13(2):1287–1292. https://doi.org/10.1016/j.dsx.2019.01.048
Acknowledgements
AD acknowledges CSIR-IICT’s institutional support. The fellowships provided by UGC-JRF/SRF to SC, ICMR-JRF/SRF to NRD, and CSIR-JRF/SRF to SC (as per sequential occurrence in the author's list) are gratefully acknowledged. (Manuscript Communication number CSIR-IICT/Pubs./2023/152).
Funding
The authors declare that no funds or grants were received during the preparation of this manuscript.
Author information
Authors and Affiliations
Contributions
AD—Study concept and design; analysis and interpretation of data; drafting of the manuscript; critical revision of the manuscript for important intellectual content; obtained funding; study supervision. SC—Acquisition of data; analysis and interpretation of data; drafting of the manuscript; critical revision of the manuscript. NRD—Acquisition of data; analysis and interpretation of data; drafting of the manuscript. SC—Acquisition of data; analysis and interpretation of data; drafting of the manuscript; critical revision of the manuscript.
Corresponding author
Ethics declarations
Conflict of interests
The authors have no financial or non-financial interests to disclose.
Ethical approval
All the procedures involving animals followed the guidelines provided by the national ‘Committee for the Purpose of Control and Supervision of Experiments on Animals (CPCSEA)’ and institutional animal ethics committee (IAEC) (approval no. IICT/IAEC/007/2019, and IICT/IAEC/025/2022).
Consent to Publish
Not applicable since the study did not involve any human subjects.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Choudhury, S., Dhoke, N.R., Chawla, S. et al. Bioengineered MSCCxcr2 transdifferentiated keratinocyte-like cell-derived organoid potentiates skin regeneration through ERK1/2 and STAT3 signaling in diabetic wound. Cell. Mol. Life Sci. 81, 172 (2024). https://doi.org/10.1007/s00018-023-05057-3
Received:
Revised:
Accepted:
Published:
DOI: https://doi.org/10.1007/s00018-023-05057-3