Organogenesis, 11:95–104, 2015 Ó 2015 Taylor & Francis Group, LLC ISSN: 1547-6278 print / 1555-8592 online DOI: 10.1080/15476278.2015.1086052
REVIEW
Wnt signaling induces epithelial differentiation during cutaneous wound healing Khosrow S Houschyar,1,2,* Arash Momeni,1 Malcolm N Pyles,1 Zeshaan N Maan,1 Alexander J Whittam,1 and Frank Siemers2 1
Division of Plastic and Reconstructive Surgery; Department of Surgery; Stanford School of Medicine; Stanford, CA USA 2 Clinic for Plastic and Reconstructive Surgery; Bergmannstrost Halle, Germany
ABSTRACT. Cutaneous wound repair in adult mammals typically does not regenerate original dermal architecture. Skin that has undergone repair following injury is not identical to intact uninjured skin. This disparity may be caused by differences in the mechanisms that regulate postnatal cutaneous wound repair compared to embryonic skin development and thus we seek a deeper understanding of the role that Wnt signaling plays in the mechanisms of skin repair in both fetal and adult wounds. The influence of secreted Wnt signaling proteins in tissue homeostasis has galvanized efforts to identify small molecules that target Wnt-mediated cellular responses. Wnt signaling is activated by wounding and participates in every subsequent stage of the healing process from the control of inflammation and programmed cell death, to the mobilization of stem cell reservoirs within the wound site. Endogenous Wnt signaling augmentation represents an attractive option to aid in the restoration of cutaneous wounds, as the complex mechanisms of the Wnt pathway have been increasingly investigated over the years. In this review, we summarize recent data elucidating the roles that Wnt signaling plays in cutaneous wound healing process. KEYWORDS. ß-catenin, regeneration, repair, stem cells, skin, Wnt
INTRODUCTION Regeneration is the process of restoration, renewal, and growth that fosters the ability
for genomes, cells, and organs to be resilient to the natural fluctuations and events that cause damage. It is important to distinguish between repair, healing via formation of scar
*Correspondence to: Khosrow S Houschyar; Email:
[email protected] Submitted: April 3, 2015; Revised August 13, 2015; Accepted August 19, 2015. 95
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tissue, and regeneration, which is restoration to the pre-injury state. Full-thickness skin loss in adult mammals typically results in a reparative rather than regenerative response, leading to the formation of scar tissue.1 Deposition of a collagen-rich matrix in the neo-dermis makes it prone to contracture, decreases elasticity and tensile strength, and promotes hypertrophic scar formation.2 Epithelialization without the development of an epidermal appendage over a large surface area leads to alopecia and thermal imbalance.3 Processes involved in the healing of a skin wound parallel embryonic skin development in many ways. Both processes involve the differentiation, migration, proliferation, and apoptosis of various cell types to create the multilayered tissue that constitutes the skin. Many of the same key signaling pathways that are activated during embryonic skin development are also activated during postnatal wound healing; e.g. Wnt/ß-catenin, Notch, and Hedgehog pathways.4 Maintenance of epidermal homeostasis is achieved by separate populations of stem cells in the skin which includes stem cells from the bulb region of the hair follicles, the interfollicular epidermis, and the sebaceous glands.5 While both epidermal and bulb stem cells have demonstrated the potential to regenerate epidermis,6,7 an effective cell-based approach utilizing these population to promote “scarless” wound healing remains elusive. There is increasing evidence that Wnt proteins are necessary for normal skin development.8,9,10 Recent data demonstrate that the epidermis of wounded adult mice can regenerate new hair follicles during healing and that the origins of cells that develop new hair follicles are Wntresponsive interfollicular stem cells, not stem cells from the existing hair follicle bulb.11 In the following sections we present a summation of data which provides strong evidence that augmenting the endogenous Wnt pathway improves cutaneous regeneration after injury through activation of tissue-resident stem cells.4,12-14
The three different Wnt signaling pathways The Wnt signaling pathway is an evolutionarily conserved pathway that regulates crucial aspects of cell fate determination, cell polarity, cell migration, neural patterning and organogenesis during embryonic development. Intracellular Wnt signaling diversifies into 3 main branches: 1. the b-catenin pathway (canonical Wnt pathway), which activates target genes in the nucleus; 2. the planar cell polarity (PCP) pathway, which involves jun N-terminal kinase (JNK) and cytoskeletal rearrangements; and 3. the Wnt/Ca2C pathway. In humans, there are currently 19 different known Wnt proteins and 10 different Frizzled receptors. This review will focus on canonical/ß-catenin dependent Wnt signaling, which has been implicated in tissue regeneration and repair. The hallmark of canonical Wnt signaling is the accumulation and translocation of the adherens junction-associated protein, b-catenin, into the nucleus.15 Without Wnt signaling, cytoplasmic b-catenin is degraded by a b-catenin destruction complex, which includes Axin, adenomatosis polyposis coli (APC), glycogen synthase kinase 3 (GSK3), protein phosphatase 2A (PP2A), and casein kinase 1a (CK1a). Phosphorylation of b-catenin within this complex by Casein Kinase and GSK3 targets it for ubiquitination and subsequent proteolytic destruction by the proteosomal complex. Binding of Wnt to its receptor complex composed of the Fz (frizzled) and the LRP5/6 triggers a series of events that disrupt the APC/Axin/ GSK3 complex that is required for the targeted destruction of b-catenin. The binding of Wnt to the Fz/LRP5/6 complex induces the membrane translocation of a key negative regulator of signaling. Binding of Axin has been proposed as the mechanism for reduction of the inhibitory activity of Axin on canonical Wnt signaling.53 This leads to activation of the phosphoprotein Dishevelled (Dsh), which inhibits the activity of the GSK3 enzyme, preventing the degradation of b-catenin, allowing consequent stabilization and accumulation in the cytoplasm. Stabilized b-catenin translocates into the nucleus, exerting its effect on
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gene transcription by functioning as a transcriptional co-activator. A large number of binding partners for b-catenin in the nucleus has been uncovered and perhaps the best characterized are the members of the LEF/TCF DNA-binding transcription factors. This complex binds to the promoter of target genes (e.g., Cyclin D1, MT1-MMP (membrane-type 1-matrix metalloproteinase), MMP-7 or Dkk-1 (Dickkopf) and these genes are required for organizer formation during embryogenesis.16 (Fig. 1).
The role of Wnt signaling in tissue regeneration/repair The Wnt pathway regulates cell proliferation in the adult epidermis, which directly impacts the rate and extent of skin wound healing. Using the Axin2-Cre lineage reporter mice, one study was able to show that the majority of the
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basal epidermal layer requires Wnt/b-catenin signaling to proliferate and these same cells contribute robustly to wound healing, with no requirement for a quiescent stem cell subpopulation.13 Wnt proteins also serve as niche signals for at least 2 types of skin stem cells that contribute to skin wound healing; those in the bulge region of the hair follicle,(17) and those in the basal layer of the interfollicular epidermis.18 Several lines of other evidence indirectly supports a role for Wnt signaling in cutaneous repair.12,19,20 The concept that wound healing recapitulates embryonic development is illustrated by the interesting finding that the source of new follicles is not cells within the hair follicle stem cell niche.21 Recent studies showed that fibroblast growth factor (FGF) signaling plays multiple inductive roles during development of vertebrates.22 FGF-9 modulates hair follicle regeneration after skin injury in adult mice and FGF-9 triggers Wnt expression with subsequent
FIGURE 1. Canonical Wnt signaling pathway. In the absence of signal, action of the destruction complex (CKIa, GSK-3b, APC, Axin) creates a hyperphosphorylated b-catenin, which is a target for ubiqitination and degradation by the proteosome. Binding of Wnt ligand to a Frizzled/LRP-5/6 receptor complex leads to stabilization of hypophosphorylated b-catenin, which interacts with TCF/ LEF proteins in the nucleus to activate transcription. In a canonical pathway, CKIa, GSK-3b, APC, and Axin act as negative regulators and all other components act positively. Abbreviations: APC D adenomatous polyposis coli, CK D casein kinase, GSK D glycogen synthase kinase, Fzd D Frizzled-Rezeptor, LRP D low-density-lipoprotein receptor related protein, Tcf/Lef D T cell-specific transcription factor/lymphoid enhancer-binding factor.
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Wnt activation in wound fibroblasts.23 Through a unique feedback mechanism, activated fibroblasts then express FGF-9, thus amplifying Wnt activity throughout the wound dermis during a crucial phase of skin regeneration (Fig. 2). Skin wounds express various Wnt proteins during the early phases of healing, with transcripts of Wnts 1, 3, 4, 5a, and 10b being present in murine full-thickness cutaneous wounds up to 7 d after injury.24 In the epithelium, Wnt 10b protein can be detected in migrating epithelial cells up to 3 d after wounding, while Wnt 4, 5a, and 10b localize to hair follicles.25 Wnt 2a and 4 are expressed in the dermis, although reports vary with respect to the time-course of their expression (range: 30 h – 7 d after wounding). It appears that Wnt
signaling, through its ability to activate stem cells with induction of their self-renewal and proliferation, serves as a positive stimulus for wound repair.
STAGES OF SKIN REGENERATION Hemostasis and inflammation are dependent on Wnt signaling Wound healing is classically described as a process involving 3 overlapping phases (Fig. 3). The resolution of injury begins with hemostasis. Vasoconstriction and clot formation lead to cessation of bleeding. Hemostasis is achieved through the activation of platelets and the
FIGURE 2. Wnt signaling maintains the hair-inducing activity in skin repair. Fibroblast growth factor (Fgf) 9 is a secreted signaling molecule that is expressed in epithelium. Mesenchymal Fgf signaling interacts with b-catenin-mediated Wnt signaling in a feed-forward loop that functions to sustain mesenchymal Fgf responsiveness and mesenchymal Wnt/b-catenin signaling. Wnt2a is a canonical Wnt ligand that activates mesenchymal Wnt/b-catenin signaling, whereas Fgf9 is the only known ligand that signals to mesenchymal Fgf receptors (FGFRs). Mesothelial Fgf9 and mesenchymal Wnt2a are principally responsible for maintaining mesenchymal Fgf-Wnt/b-catenin signaling, whereas epithelial Fgf9 primarily affects epithelial branching. In summary, Fgf signaling is primarily responsible for regulating mesenchymal proliferation, whereas b-catenin signaling is a required permissive factor for mesenchymal Fgf signaling. Abbreviations: Fgf D Fibroblast growth factor.
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FIGURE 3. There are 3 classic stages of wound repair: inflammation (a), proliferation (b) and remodeling (c). (a) Inflammation. This stage lasts until about 48 h after injury and depicted is a skin wound at about 24–48 h after injury. The wound is characterized by a hypoxic (ischemic) environment in which a fibrin clot has formed and platelets aggregate. Platelets adhere to the injured endothelium and release chemokines, thereby attracting the cellular components of the inflammatory stage. The inflammatory stage of wound healing is characterized by the presence of neutrophils, macrophages, lymphocytes and local Wnt signaling begins to increase. The inflammatory cells then serve to release proinflammatory cytokines, growth factors and vascular endothelial growth factor, ingest foreign materials, increase vascular permeability, and promote fibroblast activity. (b) Proliferation. This stage occurs about 2–10 d after injury and depicted is a skin wound at about 5– 10 d after injury. This stage includes an increased local Wnt response, capillary growth and granulation tissue formation occur and an eschar has formed on the surface of the wound. (c) Remodeling. This stage lasts for a year or longer and depicted is a skin wound about 1–12 months after repair. The final stage of wound healing is a long process of tissue remodeling and increasing wound strength. During this stage, type I collagen synthesis and turnover continues, and fibroblasts differentiate into myofibroblasts, allowing further wound contraction.
coagulation cascade.26 Recent data suggests that Wnt signaling is essential for development of megakaryocytes and for stimulating proplatelet function in vitro.27 Interestingly, canonical Wnt has been shown to inhibit platelet aggregation.28 whereas non-Canonical Wnt-5A, stimulates platelet aggregation.29
Following hemostasis is the start of the inflammatory phase which is characterized by the presence of erythema (rubor), warmth (calor), edema (tumor), and pain (dolor).30 At a cellular level, inflammation involves blood vessel dilation, increased vascular permeability, and leukocyte recruitment to the site of injury. Two
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leukocyte populations sequentially dominate the inflammatory events of wound healing: neutrophils and macrophages.31 Both provide the critical function of wound debridement, whereas the latter population is critical in orchestrating the subsequent steps in wound healing. More recently, Wnt signaling has been shown to be involved in the regulation of inflammatory processes. Wnt5a is induced in human macrophages in response to mycobacteria and conserved bacterial structures, contributing to the regulation of pro-inflammatory cytokines via its receptor Frizzled (Fzd) 5.32 Wnt5a is also induced in other infectious and inflammatory diseases such as tuberculosis, sepsis, psoriasis, rheumatoid arthritis and atherosclerosis.32 ß-Catenin-dependent Wnt signaling, therefore, robustly enhances the inflammatory response.33
Proliferation Wound debridement is critical in enhancing the inflammatory process by reducing wound bacterial counts and removing necrotic tissue which impedes the healing process.34 Once debrided, the wound enters the proliferative phase which takes place around post-injury days 4 through 12. During this time period, fibroblasts, smooth muscle cells, and endothelial cells infiltrate the wound as epithelial cells begin to cover the site of injury.35 In concert, these cells reestablish tissue continuity through matrix deposition, angiogenesis, and epithelialization. ß-Catenin is an important regulator of fibroblast behavior during the proliferative phase of dermal wound repair.36 ß-Catenin protein levels and transcriptional activity are elevated in dermal fibroblasts during the proliferative phase of healing in murine cutaneous wounds and return to baseline during the remodeling phase. Human wounds similarly show increased expression of ß-catenin and its target genes, such as fibronectin and MMP7, during the proliferative phase.37 While increased ß-catenin activity during the proliferative phase is crucial for successful wound repair, prolonged or aberrant ß-catenin activity beyond the normal parameters of healing contributes to excessive fibrosis and scar formation. Indeed, human hypertrophic scars and keloids exhibit elevated ß-catenin levels.38
Interestingly, while Wnt ligands may participate in stimulating dermal ß-catenin during wound repair, Wnt signaling is not crucial for maintaining elevated ß-catenin levels during the proliferative phase of cutaneous healing. This has been demonstrated in mice treated with an adenovirus expressing the Wnt signaling inhibitor Dickkopf (DKK1, which binds LRP6/Arrow), without a significant decline in ß-catenin protein levels during the proliferative phase of skin wound healing, in contrast to the situation in bone repair.39 This suggests that other factors play a role in regulating ß-catenin levels during the proliferative phase of healing. Indeed, ß-catenin levels in fibroblasts can be stimulated by growth factors, such as TGF-ß1, which are released during the early stages of wound repair. Furthermore, ß-catenin activity in dermal fibroblasts is regulated by extracellular matrix (ECM) components, such as fibronectin, which activates ß-catenin through a GSK3ß-dependent, ß1 integrin mediated pathway.40 Hypertrophic scars and keloids represent a dysregulated response to cutaneous wounding, resulting in an excessive deposition of ECM, especially collagen. TGF-b is believed to be responsible for excessive ECM deposition in hypertrophic scars, keloids and other fibrotic conditions.41 Since b-catenin is known to accumulate during fibroproliferation,42 we speculate that it could play a role in the mechanisms that lead to hypertrophic/keloid scarring. ß-Catenin and Wnt signaling are intrinsically involved in the formation of the dermis and of epidermal structures, both during wound repair and during skin development. It will be interesting to elucidate whether non-Wnt activators of ß-catenin, such as ECM proteins and growth factors, modulate ß-catenin during skin development as they do during the response to injury.
Wound remodeling In the skin epithelium, remodeling consists of deposition of matrix and subsequent changes in its organization and composition over time. This final phase of wound healing occurs throughout the entire wound repair process and continues for up to 1 y after injury.43 Fibrin clot formed in the early inflammatory phase is
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replaced by granulation tissue that is rich in type III collagen and blood vessels during the proliferative phase and subsequently replaced by a collagenous scar predominantly of type I collagen.44 Wnt is responsible for the differentiation of myofibroblasts of mesenchymal stem cell;45 myofibroblasts cause wound contracture, decreasing the surface of the developing scar.46 Wnt has also been shown as critical in the process of angiogenesis and endogenous enhancement of Wnt can correct vascular defects.47 As angiogenic processes diminish, wound blood flow declines, and acute wound metabolic activity slows, eventually stopping.
DIFFERENCES BETWEEN FETAL WOUND HEALING AND ADULT WOUND HEALING Although it has been almost 3 decades since the discovery of scarless fetal healing, the key to scarless repair remains elusive.48 Investigators have now begun applying more comprehensive transcriptomic techniques to the study of scarless wound healing. In particular, there has been a focus on the time during fetal gestation when regenerative healing changes to adult wound healing with scar formation in order to understand the phenomena occurring
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immediately before and after this transition. In rats, wounds made on the 16th day of gestation (gestation period: 21 days) histologically regenerate, but wounds made on the 18th day of gestation are associated with scarring.49,50 In wounds made during the regenerative phase, the skin, including appendages and panniculus carnosus muscle, is completely regenerated, whereas the scarring reparative response does not include regeneration of the hair bulb and skin texture.51 The major objective of skin wounding research is restoration of the extracellular matrix architecture, and a subsequent return of strength and function to the injured skin. It therefore must overcome the fibrotic nature of post-natal wound healing. It is clear from studies conducted in mammals that normal skin development absolutely depends on a tight regulation of the activities of secreted signaling molecules that display potent organizing properties in the embryo.52 These signaling molecules include members of the Hedgehog (Hh), transforming growth factor-b (TGF-b), and Wnt families of secreted factors (Table 1). Based on the studies mentioned above, it is clear that fetal wound healing eventually changes over to adult wound healing. Here, we focus on a particular mode of regulation of the activity of Wnt proteins to aid in the regeneration of skin architecture after wounding.
Table 1. Summary of developmental signaling pathways in mammalian skin development and repair Signaling pathway
Skin section
Skin development
Skin repair
Wnt
Wnt
Development and morphogenesis of hair follicles Development of the dermis
Regeneration of hair follicles in large wounds Reconstitution of the dermis: fibroblast numbers and behavior, matrix production Present in regenerated hair follicles
Dermis
Sonic hedgehog
Epidermis Dermis
TGF-b
Epidermis Dermis
Notch
Epidermis Dermis
Development and morphogenesis of hair follicles Role previously unknown No significant role in hair follicle development Role previously unknown Expressed in developing dermis Epidermal differentiation Role previously unknown
Involved in dermal reconstitution: effects on matrix, cellularity and vascularity Inhibitory role in re-epithelialization Reconstitution of the dermis: fibroblast proliferation and behavior, myofibroblast formation, matrix production, wound contraction Role previously unknown Involved in dermal reconstitution:effects on macrophage behavior,angiogenesis
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CONCLUSIONS AND CLINICAL ASPECTS OF SKIN REGENERATION/ REPAIR Our understanding of skin wound healing mechanisms has progressed considerably in recent years. The wound epithelium in adult mammals is just as capable of responding to morphogenic signals from the dermis as it does in the embryo during hair placode formation. Adult stem cells have tremendous therapeutic potential, and the skin epithelium represents an enormous source of accessible stem cells that might be a starting point for generating cells to replace diseased tissue. Skin stem cells have already been used to replace skin lost to burns; whether it will be possible to use skin stem cell plasticity to engineer treatments for other disorders remains to be determined. Although increasing evidence supports a role for Wnt signaling in skin epithelial stem cell maintenance and/or determination, deregulated Wnt signaling activation has long been implicated in human cancers. Wnt signaling is essential at multiple steps during the complex organogenesis of the skin and its appendages. It is required to induce the formation of the dorsal dermis and regulates the size of the different skin appendage tracts. Later, Wnt signaling is required for the very early stages of skin appendage formation. Skin appendage distribution and pigmentation are regulated, in part by Wnt signaling. Disruption of the pathway can lead to the formation of skin appendage tumors. Any strategy that attempts to target the Wnt pathway to augment tissue regeneration will have to take into consideration the need to selectively and locally activate signaling in the tissue or area of interest, while simultaneously restricting Wnt signaling in other parts of the body. The intricate and dynamic nature of the wound environment suggests that successful therapies for treating wound healing disorders will not rely upon a single allencompassing agent, but will likely require a multitude of factors for a finely tuned attenuation of endogenous Wnt signaling during
the wound healing process. Identifying the relationships between developmental signaling pathways in adult wound repair and fetal skin development and/or regeneration will certainly propel the research community closer to this goal, and is a fruitful area of future investigation.
DISCLOSURE OF POTENTIAL CONFLICTS OF INTEREST No potential conflicts of interest were disclosed.
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