Abstract
Skin fibrosis is characterized by the excessive accumulation of extracellular matrix (ECM) caused by fibrotic disorders of the skin. In recent years, ECM stiffness has emerged as a prominent mechanical cue that precedes skin fibrosis and drives its progression by promoting fibroblasts activation. However, how stiffness influences fibroblasts activation for skin fibrosis progression remains unknown. Here, we report a positive feedback loop mediated by the mechanosensitive ion channel Piezo1 and aberrant tissue mechanics in driving skin fibrosis. Piezo1 is upregulated in fibrotic skin in both humans and mice. Piezo1 knockdown dermal fibroblasts lose their fibroproliferative phenotypes despite being grown on a stiffer substrate. We show that Piezo1 acts through the Wnt2/Wnt11 pathway to mechanically induce secretion of C-C motif chemokine ligand 24 (CCL24, also known as eotaxin-2), a potent cytokine associated with fibrotic disorders. Importantly, adeno-associated virus (AAV)-mediated Piezo1 knockdown ameliorated the progression of skin fibrosis and skin stiffness in mice. Overall, increased matrix stiffness promotes skin fibrosis through the inflammatory Piezo1-Wnt2/Wnt11-CCL24 pathway. In turn, a stiffer skin microenvironment increases Piezo1 expression to exacerbate skin fibrosis aggression. Therefore, targeting Piezo1 represents a strategy to break the positive feedback loop between fibroblasts mechanotransduction and aberrant tissue mechanics in skin fibrosis.
Similar content being viewed by others
Introduction
Skin fibrosis is a pathological process involving excessive accumulation of extracellular matrix (ECM) components caused by skin fibrotic disorders such as hypertrophic scar (HS), keloid, and scleroderma [1]. Activated fibroblasts, namely myofibroblasts, are mainly involved in the excessive production and cross-linking of ECM [2]. New insights into the pathogenesis of tissues fibrosis have been provided by the discovery that increased matrix stiffness of fibrotic tissues may contribute to a positive feedback loop with fibroblast activation [3, 4]. The accumulated deposition and remodeling of ECM continuously stimulates fibroblast activation and ECM production, further upregulating matrix stiffness, establishing this amplification loop. In this circuit, fibroblasts integrate mechanical signals from the abnormal mechanical microenvironment via mechanosensors [5]. Several key mediators, including membrane channels [6], integrins [7], focal adhesion kinase (FAK) [8] and yes-associated protein (YAP) [9], have been reported to promote fibrosis in response to matrix mechanics. However, the surface mechanosensors that directly link matrix mechanics and fibroblast activation in skin fibrosis are largely unknown.
The mechanosensitive channel Piezo1 has been shown to directly sense matrix stiffness [10]. In neural stem cell differentiation, Piezo1 provides a link between ECM mechanics and intracellular signaling [11]. In dendritic cells, Piezo1 serves as an important sensor that promotes cell metabolism and inflammatory function under environmental stiffness [12]. Monocytes also regulate angiogenesis via Piezo1 based on the mechanical properties of their surrounding matrix [13]. Importantly, Piezo1 is also essential in feedback loops that contribute to disease progression by interacting with tissue mechanics. In a Piezo1-dependent manner, glioma cells interact with aberrant glioma tissue mechanics to promote malignancy [14]. In central nervous system ageing, Piezo1 provides a negative feedback mechanism for oligodendrocyte progenitor cell proliferation and prefrontal cortex stiffness [15]. A positive feedback regulation between the cell cytoskeleton and Piezo1 activity also promotes inflammatory activation of macrophages [16]. We have previously shown that Piezo1 is involved in mechanical stretch-induced hypertrophic scar formation [17]. However, it is unknown whether aberrant matrix stiffness interacts with fibroblast Piezo1 to promote skin fibrosis. Therefore, we postulated a positive feedback loop in which Piezo1 interacts with fibrotic skin matrix stiffness to exacerbate skin fibrosis.
Here we report that Piezo1 is overexpressed in fibrotic human and mouse skin tissues, particularly in myofibroblasts. In vitro, increased substrate stiffness upregulates Piezo1 expression in human dermal fibroblasts (HDFs) and promotes HDF activation through the Piezo1 channel. Using a cytokine antibody array, we identified the Piezo1 downstream cytokine CCL24, which is linked to HDFs activation via inflammatory pathways. Furthermore, using RNA sequencing (RNA-seq), we highlight the critical role of Wnt2/Wnt11 as intracellular signaling connecting Piezo1 with CCL24 secretion. Finally, in a mouse skin fibrosis model, application of AAV-mediated Piezo1 knockdown effectively reduces skin fibrosis progression and skin stiffness. Collectively, our data provide direct insight into the molecular mechanism of skin fibrosis progression by uncovering an ECM stiffness-driven positive feedback loop that can manipulate dermal fibroblast activation by activating the Piezo1-Wnt2/Wnt11-CCL24 inflammatory signaling pathway.
Results
Piezo1 expression is upregulated in skin fibrosis
To investigate mechanosensation in HDFs, we first examined the expression of mechanically activated cation channels (MACs) in HDFs. RT-qPCR confirmed that Piezo1 expression is higher than other reported MACs (Fig. 1A). We then investigated the protein level of Piezo1 in normal skin, hypertrophic scar and keloid tissues from humans. Western blot confirmed that Piezo1 is overexpressed in human fibrotic skin tissues (Supplementary Fig. 1A). Immunohistochemical analysis confirmed an increase in Piezo1 in human fibrotic skin tissues (Fig. 1B). As shown by α-SMA/Piezo1 immunofluorescence co-staining, we observed that Piezo1 is highly expressed in myofibroblasts in human fibrotic skin tissues (Fig. 1C). We also examined Piezo1 expression in MDFs. MDFs also show high expression of Piezo1 and negligible levels of other MACs (Fig. 1D). Western blot confirmed that Piezo1 is overexpressed in mouse fibrotic skin tissues (Supplementary Fig. 1B). Immunohistochemical analysis revealed that Piezo1 is overexpressed throughout the dermis in the bleomycin-induced skin fibrosis mouse model (Fig. 1E). Immunofluorescence staining with Piezo1 and α-SMA shows that Piezo1 is overexpressed in mouse dermal myofibroblasts, similar to the phenomenon observed in human fibrotic skin tissue (Fig. 1F). Taken together, these results suggest that Piezo1 may be associated with mechanical stiffness-mediated progression of skin fibrosis.
Increased matrix stiffness stimulates Piezo1 overexpression and Piezo1-dependent HDFs activation
Previous reports have described that increased matrix stiffness leads to Piezo1 overexpression [18]. Therefore, we speculate that aberrant matrix stiffness of fibrotic skin promotes Piezo1 expression in vivo. We then cultured HDFs on hydrogels of varying stiffness from 2 to 50 kPa (mimicking the elastic range of normal skin and fibrotic skin tissue). Notably, we observed that Piezo1 expression was upregulated by the increased matrix stiffness (Fig. 2A). We then investigated the role of Piezo1 in the activation of HDFs induced by increased matrix stiffness. The EdU proliferation assay showed that increased substrate stiffness-induced cell proliferation was downregulated after si-Piezo1 treatment (Fig. 2B). However, apoptosis of HDFs showed no significant difference in all groups (Fig. 2C). Increased matrix stiffness stimulated the expression of ECM components (fibronectin, Col3 and Col1) and α-SMA in HDFs, and Piezo1 knockdown abolished the overexpression of these proteins (Fig. 2D). Similarly, α-SMA immunostaining and collagen contraction assay confirmed that increased matrix stiffness could upregulate α-SMA expression through the Piezo1 channel (Fig. 2E, F). Taken together, these results suggest that mechanical stiffness-induced activation of HDFs could be regulated by Piezo1 activity.
CCL24 was identified as a Piezo1 downstream cytokine in response to mechanical stiffness
As inflammatory mechanisms are strongly implicated in the progression of skin fibrosis [19], we investigated whether Piezo1 modulates cytokine signaling. Notably, as suggested by our cytokine antibody arrays, levels of CCL24 (also known as eotaxin-2), a chemokine strongly associated with dermal and pulmonary fibrosis [20], were lower in Piezo1 knockdown HDFs grown on higher substrate stiffness (Fig. 3A). Consistent with the cytokine antibody arrays, PCR and in vitro ELISA assay further confirmed that increased matrix stiffness could stimulate CCL24 secretion through Piezo1 activation (Fig. 3B). In addition, expression of CCR3 (the surface receptor for CCL24) was reduced in Piezo1-deficient HDFs cultured on higher mechanical stiffness (Fig. 3C). Importantly, CCL24/CCR3 expression is present in fibrotic human and mouse skin tissues, particularly in myofibroblasts (Fig. 3D–K). To fully elucidate whether CCL24 could directly modulate HDFs activation, human CCL24 protein was added to the HDFs culture media. We observed that CCL24 promoted HDFs proliferation (Supplementary Fig. 2A, B), ECM components/α-SMA production (Supplementary Fig. 2C–F) and cellular contraction (Supplementary Fig. 2G, H) in a dose- and time-dependent manner. Collectively, these results indicate that CCL24-dependent inflammatory pathways play a critical role in Piezo1-mediated HDFs activation in response to mechanical stiffness.
Wnt2/Wnt11 pathways were identified as a Piezo1 downstream pathway in response to mechanical stiffness
To elucidate candidate pathways linking Piezo1 to CCL24 secretion, we performed RNA-seq between si-Piezo1 HDFs and si-Ctrl HDFs grown on higher substrate stiffness (Fig. 4A). As expected, in GO enrichment analysis, Piezo1 knockdown mainly decreased ECM production, consistent with our in vitro assay (Fig. 4B). In KEGG enrichment analysis, Piezo1 knockdown resulted in downregulation of cytokine-cytokine receptor interaction, suggesting a role for Piezo1 in cytokine-based fibrosis paradigms (Fig. 4C). We further focused on the downregulation of “Wnt signaling pathway” in the KEGG enrichment analysis, as Wnt signaling pathway was identified as a mechanoresponsive pathway [21] and a downstream mediator of Piezo1 according to previous report [22]. In the Wnt pathway, Wnt2 and Wnt11 were highly expressed. Importantly, Wnt2 and Wnt11 were also highly expressed in GO enrichment top-down regulated pathways such as “extracellular space”, “collagen-containing extracellular matrix”, “extracellular region”, “extracellular matrix”, “cell–cell signaling” and “cytokine activity”, which are related to ECM synthesis and cytokine signaling (Fig. 4D). Thus, Wnt2/Wnt11 are key mediators in Piezo1-induced ECM production and inflammatory mechanism. Western blotting confirmed that mechanical stiffness upregulates Wnt2/Wnt11 expression through Piezo1 (Fig. 4E, F). In human and mouse fibrotic skin tissues, Wnt2/Wnt11 are also overexpressed in the dermis and myofibroblasts (Fig. 4G–N). Thus, these results demonstrate that Wnt2/Wnt11 serve as a key target of Piezo1 mechanotransduction.
The role of inflammatory Piezo1–Wnt2/Wnt11–CCL24 pathways in HDFs activation
We next investigated the role of Wnt2/Wnt11 in mechanical stiffness-induced HDFs activation. EdU staining revealed that increased substrate stiffness-induced cell proliferation was downregulated after si-Wnt2 or si-Wnt11 treatment (Fig. 5A, B). Wnt2/Wnt11 is also involved in mechanical stiffness-induced activation of HDFs, including synthesis of ECM components, α-SMA production and contractility (Fig. 5C–H). Most importantly, Wnt2/Wnt11 inhibition blocked mechanical stiffness-induced CCL24 release (Fig. 5I, J) and CCR3 overexpression (Fig. 5K, L), highlighting the key role of the Piezo1-Wnt2/Wnt11-CCL24 axis in mechanotransduction and inflammation in HDFs. Wnt signaling has been reported to include the canonical β-catenin pathway and non-canonical pathways. In fibroblast activation, Wnt2 is usually involved in the canonical β-catenin pathway and Wnt11 is usually involved in the non-canonical pathways (activation of JUN N-terminal kinase (JNK) via phosphorylation). In our data, we confirmed that mechanical stiffness could stimulate the Wnt2/β-catenin pathway (Fig. 5M) and the Wnt11/JNK pathway (Fig. 5N). Taken together, these data highlight the critical role of the Piezo1-Wnt2/Wnt11-CCL24 pathway in the activation of HDFs.
Overexpressed Wnt2 and Wnt11 rescue HDFs activation in the context of Piezo1 knockdown
To investigate whether overexpression of Wnt2/Wnt11 in HDFs could rescue Piezo1-loss phenotypes, we overexpressed Wnt2/Wnt11 by virus. Western blot showed that Wnt2/Wnt11 was overexpressed in HDFs (Supplementary Fig. 3). In our assay, Wnt2/Wnt11 overexpression rescued the proliferation of HDFs in Piezo1-loss background (Fig. 6A, B). Furthermore, Wnt2/Wnt11 overexpression also rescued activation of HDFs, including the synthesis of ECM components, α-SMA production and cellular contractility (Fig. 6C–H). As shown by PCR and in vitro ELISA assay, Wnt2/Wnt11 overexpression increased CCL24 release (Fig. 6I, J). Collectively, our data confirmed that Wnt2/Wnt11 served as an important mediator in the Piezo1-CCL24 pathway in the activation of HDFs.
AAV9-targeting Piezo1 knockdown attenuates skin fibrosis progression and skin stiffness in bleomycin-induced mice skin fibrosis model
In mechanical stiffness-induced central nervous system ageing, AAV-mediated Piezo1 knockdown significantly improves cellular regenerative capacity [15]. To clarify the critical role of Piezo1 in promoting mechanical stiffness-induced skin fibrosis, we investigated the effects of AAV9-shPiezo1 treatment in the bleomycin-induced mouse skin fibrosis model. We injected AAV9-shPiezo1 and AAV9-shCtrl into the dorsal skin of mice. After three weeks, Piezo1 expression was significantly reduced in AAV9-shRNA-treated mice compared to AAV9-shCtrl-treated mice (Supplementary Fig. 4). Subsequently, skin fibrosis was induced by bleomycin injections for four weeks (Fig. 7A). Importantly, bleomycin-induced fibrosis was significantly less severe in AAV9-shPiezo1-treated mice compared to AAV9-shCtrl-treated mice, with reduced skin thickness and collagen deposition (Fig. 7B). We next determined whether Piezo1 knockdown reduced mechanical stiffness of the skin. AAV9-shPiezo1 treated mice had significantly reduced tensile strength (Fig. 7C). Using immunostaining, we observe that Piezo1 knockdown downregulates the number of α-SMA+ myofibroblasts in vivo (Fig. 7D). AAV9-shPiezo1 also reduced the levels of Piezo1 downstream signaling (Wnt2; Wnt11; CCL24; CCR3) (Fig. 7E, F) and Wnt2/Wnt11 downstream signaling (β-catenin; pJNK) (Fig. 7G) in bleomycin-treated mice. Importantly, we performed intradermal administration of recombinant mouse CCL24 in our animal model. We observed that CCL24 injection restored the fibrotic phenotype of Piezo1-deficient mice upon bleomycin stimulation, confirming the key role of the Piezo1-CCL24 axis in skin fibrosis (Supplementary Fig. 5). Taken together, our data confirmed the role of the Piezo1-Wnt2/Wnt11-CCL24 pathway in mechanical stiffness-induced skin fibrosis.
Discussion
The interplay between mechanical stiffness and biochemical signaling pathways controls the initiation and progression of tissue fibrosis [23]. This process forms a positive feedback loop with increased matrix stiffness and fibroblast activation [24]. In this loop, increased matrix stiffness promotes fibroblast differentiation, then ECM proteins produced by these activated myofibroblasts further upregulate matrix stiffness, completing this amplification loop. Although the effect of the inflammation-mediated positive feedback loop on skin fibrosis has been described [25], the mechanosensitive molecules that detect abnormal matrix stiffness and translate mechanical stiffness into intracellular signaling have not been fully identified.
Piezo1-mediated mechanotransduction is critical for fibrosis progression [26, 27]. We therefore propose a previously unrecognized in vivo role for Piezo1 in promoting skin fibrosis aggression by establishing a positive feedback loop. Piezo1 is overexpressed in myofibroblasts of human and mouse fibrotic skin tissues, suggesting that higher tissue mechanics may trigger Piezo1 expression. Piezo1 expression is also upregulated at higher substrate stiffness in vitro, confirming previous findings that increased tissue mechanics could stimulate Piezo1 expression in different cell types [28,29,30]. Importantly, our data confirmed that mechanical stiffness could promote the activation of dermal fibroblasts through the Piezo1 channel. In cardiac fibrosis, Piezo1 is involved in matrix stiffness-induced activation of cardiac fibroblasts [24]. This association between Piezo1 expression and fibroblast activation is consistent with increasing matrix stiffening, and Piezo1 upregulation and function may be amplified to exacerbate fibroblast activation. Collectively, this phenomenon suggests that Piezo1-mediated mechanosensation may serve as a general mechanism for dermal fibroblasts to sense and respond to their abnormal tissue mechanics in skin fibrosis.
In several different organ systems, cytokines have been identified as key inducers of fibrosis [31]. Studies have shown that Piezo1 activation results in the secretion of several known cytokines, including FGF1 [32], IL-6 [33], TNF-α [34] and TGF-β [35]. It is possible that in addition to Piezo1-mediated fibroblast activation, Piezo1 may also control fibroblasts activation through cytokine-mediated mechanisms. We therefore investigated whether Piezo1 modulates cytokine signaling in fibroblasts activation and then focused on the downregulation of CCL24 in the context of Piezo1 knockdown. CCL24 is a chemokine that stimulates immune cell trafficking and activation as well as profibrotic activities through the receptor CCR3 [36]. Previous studies have shown that both CCL24 and CCR3 are involved in skin and lung inflammation and fibrosis [37, 38]. CCL24 has been shown to promote collagen production in human lung fibroblasts and plays a critical role in promoting profibrotic effects in idiopathic pulmonary fibrosis (IPF) [39]. Our research has shown that CCL24 promotes the activation of dermal fibroblasts. In recent years, there has been increasing evidence that Piezo1 links physical forces to inflammation in several physiological processes. Piezo1 is activated in response to cyclic pressure and drives c-JUN activation, endothelin-1 overexpression and HIF1α stabilization, facilitating the pro-inflammatory program in mouse lung fibrosis [40]. In aortic valve stenosis, Piezo1 was identified as the main mechanoreceptor responsible for driving monocyte and plasma inflammatory phenotypes [41]. Macrophages lacking Piezo1 also exhibit reduced inflammation and enhanced wound healing responses [16]. Collectively, our results highlight a novel mechanosensory inflammatory axis in which the CCL24-dependent inflammatory pathway plays an important role in Piezo1-mediated dermal fibroblasts activation.
We further elucidate the intracellular signaling Wnt2/Wnt11 that links Piezo1 to CCL24 secretion. Several reports have confirmed that Wnt signaling serves as a downstream mediator of Piezo1. In osteoblast differentiation, Piezo1 activation mediates mechanotransduction via the Wnt/β-catenin pathway [22]. Cyclic mechanical force affects cardiac function-associated protein expressions through the Piezo1/Wnt pathway [42]. Wnt signaling is involved in a variety of physiological processes, and aberrant regulation of this pathway has been implicated in a number of diseases, including cancer and fibrosis [43]. Recent studies have implicated Wnt2 and Wnt11 in the progression of cardiac and pulmonary fibrosis [44,45,46,47]. In particular, Wnt2 and Wnt11 expression is increased in skin fibrosis [48], providing new evidence for a potential role of Wnt antagonists in regulating ECM composition in skin fibrosis. Direct regulation of Wnt signaling by mechanical cues has been demonstrated. Extracellular mechanical cues regulate intestinal organoid growth by increasing Wnt/β-catenin signaling [49]. Mechanical features of the microenvironment influence the tissue-specific differentiation of stem cells through an enhanced Wnt-dependent mechanism [50]. Strikingly, in mechanical force-mediated tissue fibrosis, Wnt11 may be a novel therapeutic target for the prevention of cardiac fibrosis under pressure overload [45]. Therefore, together with our findings, we highlight the important role of Wnt2/Wnt11 in linking Piezo1 and aberrant tissue mechanics mediated fibrosis. In addition, recent evidence has shed light on the cellular processes by which Wnt signaling and conventional inflammatory cytokines control disease progression [51]. Cancer cells lacking p53 induced the secretion of Wnt ligands, which stimulate tumor-associated macrophages to produce IL-1β, thereby dictating pro-metastatic systemic inflammation [52]. In a novel transgenic mouse model of overload proteinuria, activation of Wnt/β-catenin signaling enhances intrarenal inflammation via the TLR-4/NLRP-3 inflammasome axis [53]. After Wnt2 or Wnt11 knockdown, both CCL24 and CCR3 expression were downregulated in fibroblasts cultured on higher substrate stiffness. Taken together, these results suggest that mechanical stiffness regulates fibroblast activation through the Piezo1-Wnt2/Wnt11-CCL24 inflammatory pathway.
Gene therapy has been increasingly successful owing to enhanced molecular understanding of human disease and the development of gene delivery technologies [54]. Among these technologies, adeno-associated virus (AAV) delivery vectors have proven to be safe and effective [55]. AAV also holds promise as a useful vector for skin-directed gene therapy in chronic wound healing [56, 57]. In our research, AAV-targeted Piezo1 knockdown effectively ameliorates the progression of skin fibrosis and skin rigidity in mice. Similarly, AAV delivery shows therapeutic potential in the treatment of fibrotic diseases. For example, AAV-mediated silencing of CD47 [58], KDM4D [59] and nestin [60] has been used as a strategy to reduce liver fibrosis. Localized AAV-mediated inhibitor of differentiation 3 gene therapy in rabbit eyes abolished corneal fibrosis in vivo [61]. Overall, our findings may provide a new genetic therapeutic avenue for the treatment of skin fibrosis and, more importantly, mechano-based therapeutics targeting Piezo1 showed promising results in breaking the positive feedback loop between cell mechanotransduction and aberrant tissue mechanics.
There are several limitations to this study. Indeed, it has been reported that Piezo1, Wnt2/Wnt11 and CCL24 play a role in the progression of skin fibrosis. Hence, the level of research innovation is moderate. Our previous reports first showed that Piezo1 plays an important role in mechanical force-induced skin fibrosis [17, 62]. However, the mechanism between Piezo1 and skin fibrosis is not clear. Since inflammation serves as a driver in the progression of skin fibrosis [63], we speculate whether Piezo1 links cytokines/chemokines in skin fibrosis. Using cytokine antibody arrays, we selected CCL24, a chemokine strongly associated with tissue fibrosis. We then identified Wnt2/Wnt11 as the link between Piezo1 and CCL24. Thus, we show that Piezo1-Wnt2/Wnt11-CCL24 is a novel positive feedback loop, especially in mechanical force-induced skin fibrosis.
Based on these findings, we propose a model for mechanical stiffness-mediated skin fibrosis in which aberrant tissue mechanics activates both dermal fibroblast activation and CCL24 via Piezo1-Wnt2/Wnt11 to maintain a positive feedback loop (Fig. 8). These studies provide a framework for understanding how mechanical stiffness triggers inflammatory responses to induce skin fibrosis progression. More broadly, these results suggest that gene therapy targeting Piezo1 could effectively uncouple mechanical stiffness from inflammation and fibrosis and may prove successful in various human diseases.
Materials and methods
Patient samples
Fresh human normal skin, hypertrophic scar, and keloid tissues (Supplementary Table 1) were collected from Shanghai Ninth People’s Hospital with ethics approval from the local Human Research Ethics Committee of Shanghai Jiao Tong University School of Medicine in accordance with the principles of the Declaration of Helsinki. Upon collection, samples were directly fixed with PFA and then processed for the following analyses.
Cell isolation and culture
The normal human skin tissues or neonatal mouse dorsal skin were placed in a 0.2% Dispase II solution (Sigma‐Aldrich, St Louis, MO, USA) overnight at 4 °C. The next day, the dermal skin was digested with 0.25% collagenase IV solution (Sigma‐Aldrich) at 37 °C for 2 h. After filtration, centrifugation, and resuspension, the human dermal fibroblasts (HDFs) or mouse dermal fibroblasts (MDFs) were cultured in Dulbecco’s Modified Eagle Medium (DMEM) (Gibco Life Technologies, Grand Island, NY, USA) supplemented with 10% fetal bovine serum (FBS) (Gibco Life Technologies) and 1% penicillin/streptomycin (Gibco Life Technologies) at 37 °C and 5% CO2. Passage 3–5 cells were used for experiments.
Quantitative real-time reverse transcriptase-PCR (RT-PCR)
TRIzol reagent was used to extract total RNA. The RNA was reverse transcribed into cDNA using RevertAid Reverse Transcriptase (Thermo Fisher Scientific, Waltham, MA, USA) according to the manufacturer’s instructions. Real-time PCR was performed with SYBR Premix EX Taq (Takara, Dalian, China) and LightCycler 480 System (Roche, Indianapolis, IN, USA). The primers used in our study are shown in Supplementary Table 2.
Histology and immunohistochemistry
Samples were fixed with 4% paraformaldehyde overnight, then embedded in paraffin. 5 mm sections were processed and stained with hematoxylin and eosin (H&E) and Masson’s Trichrome Stain Kit following protocol (Solarbio, Bei**g, China).
We used the following antibodies to investigate protein expression in these samples by immunohistochemistry: Piezo1 (ab128245, 1:100, Abcam, Cambridge, UK), CCL24 (22306-1-AP, 1:200, Proteintech, Wuhan, China), CCR3 (ab32512, 1:100, Abcam), Wnt2 (A5864, 1:200, Abclonal, Wuhan, China), Wnt11 (ab31962, 1:200, Abcam), α-SMA (#19245, 1:200, Cell Signaling Technology, Danvers, USA), p-JNK (sc-6254, 1:100, Santa Cruz Biotechnology, Dallas, Texas, USA), β-catenin(#8480, 1:100, CST). Images were captured using a Nikon Eclipse E800 microscope (Nikon, Melville, NY, USA).
Immunofluorescence
Cell samples were fixed with 4% PFA for 15 min at RT. Tissues were fixed with 4% PFA overnight at RT. Tissue samples were embedded in paraffin and sliced into 5 mm sections. Samples were incubated with following antibodies: Piezo1 (ab128245, 1:100, Abcam), α-SMA (ab7817, 1:100, Abcam), CCL24 (22306-1-AP, 1:200, Proteintech), CCR3 (ab32512, 1:100, Abcam), Wnt2 (A5864, 1:200, Abclonal, Wuhan, China), Wnt11 (ab31962, 1:200, Abcam), β-catenin(#8480, 1:100, CST), Alexa Fluor 594 goat anti-rabbit secondary antibody (Jackson lab, 125369, 1:200) and Alexa Fluor 488 goat anti-mouse secondary antibody (Jackson lab, 133384, 1:200). Images were visualized using a Nikon Eclipse E800 microscope (Nikon, Melville, NY, USA).
Polyacrylamide hydrogel-coated plates
To test the effect of matrix stiffness on HDFs behaviors, cells were seeded on collagen-coated polyacrylamide hydrogels with different stiffnesses (2 kPa and 50 kPa) for 7 days. 2 kPa plates mimic the elastic modulus of human normal skin tissues and 50 kPa plates mimic the elastic modulus of human fibrotic skin tissues according to previous report [64].
5-ethynyl-20-deoxyuridine (EdU) staining
EdU staining was detected using the Click-iT EdU Imaging Kits (Invitrogen) according to the manufacturer’s protocol. Briefly, cells were incubated with 10 mM EdU for 1 h before fixation, permeabilization, and EdU staining. The nuclear was stained with DAPI (Sigma-Aldrich, St. Louis, MO).
Apoptosis assay
The Annexin V Apoptosis Detection Kit (BD Biosciences, San Jose, CA, USA) was utilized to assess cellular apoptosis. HDFs were washed, centrifuged, and then resuspended in PBS buffer containing annexin V-FITC. The cells were incubated at room temperature for 15 min. The samples were analyzed with a Gallios flow cytometer (Beckman Coulter, Brea, CA, USA).
siRNA and transfection
For gene silencing, HDFs were transfected with 100 nM siRNA by using Lipofectamine RNAiMAX reagent (Invitrogen, Carlsbad, CA, USA) according to the manufacturer’s protocol. The sequences were as follows: Piezo1-siRNA, 5′-AGAAGAAGAUCGU CAAGUATT-3′ (sense) and 5′-UACUUGACGAUCUUC UUCUTT-3′ (antisense), Wnt2-siRNA, 5′-GUUCCUGUGAUCCAAAGAATT-3′ (sense) and 5′-UUCUUUGGAUCACAGGAACTT-3′ (antisense), Wnt11-siRNA, 5′-GAACUCGUCUAUCUGCAGATT-3′ (sense) and 5′-UCUGCAGAUAGACGAGUUCTT-3′ (antisense), Ctrl (Control)-siRNA, 5′-GUGAGCGUCUAUAUACCAUTT-3′ (sense) and 5′-AUGGUAUAUAGACGCUCACTT-3′ (antisense).
Collagen gel contraction assay
HDFs were resuspended in collagen gel (Shengyou, Hangzhou, China). Suspension was plated in each well of a 24-well plate. The plates were incubated at 37 °C for 15 min to allow collagen gel polymerization. After gel polymerization, 1 ml DMEM supplemented with 10% FBS was added to each well. The gels were photographed post 48 h.
Cytokine antibody arrays
The levels of 40 inflammatory cytokines in the supernatants of HDFs were assayed using the Human Inflammation Array Q3 based on the manufacturer’s instructions (RayBiotech Inc., Norcross, GA, USA).
Enzyme-linked immunosorbent assay (ELISA)
After the desired treatment, the culture medium was collected and centrifuged at 2500 rpm for 10 min. The supernatants were collected and the concentration of cytokines CCL24 was measured by ELISA kits from the R&D system (Minneapolis, MN, USA) in accordance with the instruction manual.
CCL24/Eotaxin-2 protein treatment
Recombinant human CCL24/Eotaxin-2 protein (HY-P7161, MedChemExpress, Shanghai, China) and Recombinant mouse CCL24/Eotaxin-2 protein (HY-P7760, MedChemExpress, Shanghai, China) was purchased and dissolved in PBS solution (Human CCL24 concentration: 5 ng/ml, 10 ng/ml, 15 ng/ml; Mouse CCL24 concentration: 10 ng/ml) according to the manufacturer’s instructions.
RNA sequencing
For RNA-seq analysis, N = 3 biological replicates were sequenced per experimental group (HDFs were pretreated with Piezo1-siRNA or NC-siRNA, then cultured in 50kPa plates for 7 days). Total RNA was extracted using the Trizol reagent. RNA integrity was assessed using the Agilent 2100 Bioanalyzer (Agilent Technologies, Santa Clara, CA, USA). Samples with an RNA Integrity Number ≥ 7 were processed for the subsequent analysis. The TruSeq Stranded mRNA LT Sample Prep Kit (Illumina, San Diego, CA, USA) was used to construct cDNA libraries. Differentially expressed genes (DEGs) were done using the R package DEseq2 (v 1.6.3) [65]. P < 0.05 and fold change >2 or fold change <0.5 was set as the threshold for a significant differential expression pattern. Hierarchical cluster analysis of DEGs was performed to examine transcript expression patterns. Gene Ontology enrichment analysis and KEGG pathway enrichment analysis of DEGs were performed using R based on the hypergeometric distribution.
Western blotting
Cells were lysed with ice-cold RIPA buffer and centrifuged at 13,000 g for 15 min at 4 °C. 10 μg of protein lysate (concentration determined by a bicinchoninic acid assay) was run on a 10% SDS-PAGE gel at 150 V for 1 h and then transferred to nitrocellulose filter membranes (Millipore, Bedford, MA). After blocking with 5% BSA at RT for 1 h, the membranes were incubated with the following primary antibodies: Piezo1 (ab128245, 1:1000, Abcam), Collagen I (ab34710, 1:500, Abcam), Collagen III (ab7778, 1:500, Abcam), fibronectin (ab2413, 1:1000, Abcam), α-SMA (#19245, 1:1000, CST), GAPDH (#5174, 1:1000, CST), CCR3 (ab32512, 1:1000, Abcam), Wnt2 (A5864, 1:1000, Abclonal), Wnt11 (bs-8568R, 1:1000, Bioss), JNK (#9252, 1:1000, CST), p-JNK (#4668, 1:1000, CST) at 4 °C overnight. The next day, membranes were incubated with an Anti-rabbit IgG, HRP-linked Antibody (7074 S, 1:1000, CST) at room temperature for 1 h and then washed with tris-buffered saline with 0.1% Tween 20 three times for 10 min. Quantitative analysis was performed on the immunoreactive bands with ImageJ software.
Animal models of fibrosis
Briefly, 8-week-old C57/BL6 mice (SLAC Laboratory Animal, Shanghai, China) were anesthetized. 100 μL of either AAV9-shPiezo1 or AAV9-shCtrl was injected subcutaneously into the dorsal skin of the mice 21 days before bleomycin injection. In the bleomycin-induced skin fibrosis model, skin fibrosis was induced by subcutaneous injection of bleomycin (Yeasen Biotechnology, Shanghai, China) for 4 weeks. All animal procedures were performed in accordance with the guidelines of the Animal Care and Use Committee of the School of Medicine, Shanghai Jiao Tong University.
Adeno-associated virus (AAV) vector construction
The construction of the vector carrying the shRNA (against Piezo1 and no-targeting scramble) and its packaging into AAV-9 were carried out by Vector Builder (vectorbuilder.com) at final titer of AAV9 to >1.0 × 1012 GC/ml. The interference sequences were as follows: AAV9-shCtrl: 5′- CCTAAGGTTAAGTCGCCCTCG-3′, AAV9-shPiezo1: 5′- CTGCTATCAGACACCATTTAT-3′. 100 μL (1.0 × 1011 GC/ml) of AAV9-shPiezo1 or AAV9-shCtrl was injected into the subcutaneous of mice dorsal skin. After 21 days, mice dorsal skin was collected and performed immunostaining analysis of Piezo1 to confirm whether the target gene has been knocked down.
Statistical analysis
A two-tailed Student’s t-test was used for comparisons between two groups. One-way ANOVA was used for comparing multiple groups. P < 0.05 was considered to indicate a significant difference. At least three independent replicates were used for each experiment. Results are expressed as the means ± SD.
Data availability
All data generated or analyzed during this study are available from the corresponding author upon reasonable request.
References
Babalola O, Mamalis A, Lev-Tov H, Jagdeo J. NADPH oxidase enzymes in skin fibrosis: molecular targets and therapeutic agents. Arch Dermatol Res. 2014;306:313–30.
Shook BA, Wasko RR, Rivera-Gonzalez GC, Salazar-Gatzimas E, López-Giráldez F, Dash BC, et al. Myofibroblast proliferation and heterogeneity are supported by macrophages during skin repair. Science. 2018;362:eaar2971.
Liu F, Mih JD, Shea BS, Kho AT, Sharif AS, Tager AM, et al. Feedback amplification of fibrosis through matrix stiffening and COX-2 suppression. J Cell Biol. 2010;190:693–706.
Parker MW, Rossi D, Peterson M, Smith K, Sikström K, White ES, et al. Fibrotic extracellular matrix activates a profibrotic positive feedback loop. J Clin Investig. 2014;124:1622–35.
Tschumperlin DJ, Lagares D. Mechano-therapeutics: targeting mechanical signaling in fibrosis and tumor stroma. Pharmacol Ther. 2020;212:107575.
Rahaman SO, Grove LM, Paruchuri S, Southern BD, Abraham S, Niese KA, et al. TRPV4 mediates myofibroblast differentiation and pulmonary fibrosis in mice. J Clin Investig. 2014;124:5225–38.
Strohmeyer N, Bharadwaj M, Costell M, Fässler R, Müller DJ. Fibronectin-bound α5β1 integrins sense load and signal to reinforce adhesion in less than a second. Nat Mater. 2017;16:1262–70.
Wong VW, Rustad KC, Akaishi S, Sorkin M, Glotzbach JP, Januszyk M, et al. Focal adhesion kinase links mechanical force to skin fibrosis via inflammatory signaling. Nat Med. 2011;18:148–52.
Liang M, Yu M, **a R, Song K, Wang J, Luo J, et al. Yap/Taz deletion in Gli(+) cell-derived myofibroblasts attenuates fibrosis. J Am Soc Nephrol. 2017;28:3278–90.
Jiang Y, Zhang H, Wang J, Liu Y, Luo T, Hua H. Targeting extracellular matrix stiffness and mechanotransducers to improve cancer therapy. J Hematol Oncol. 2022;15:34.
Pathak MM, Nourse JL, Tran T, Hwe J, Arulmoli J, Le DT, et al. Stretch-activated ion channel Piezo1 directs lineage choice in human neural stem cells. Proc Natl Acad Sci USA. 2014;111:16148–53.
Chakraborty M, Chu K, Shrestha A, Revelo XS, Zhang X, Gold MJ, et al. Mechanical stiffness controls dendritic cell metabolism and function. Cell Rep. 2021;34:108609.
Forget A, Gianni-Barrera R, Uccelli A, Sarem M, Kohler E, Fogli B, et al. Mechanically defined microenvironment promotes stabilization of microvasculature, which correlates with the enrichment of a novel piezo-1(+) population of circulating CD11b(+) /CD115(+) monocytes. Adv Mater. 2019;31:e1808050.
Chen X, Wanggou S, Bodalia A, Zhu M, Dong W, Fan JJ, et al. A feedforward mechanism mediated by mechanosensitive ion channel PIEZO1 and tissue mechanics promotes glioma aggression. Neuron. 2018;100:799–815.e7.
Segel M, Neumann B, Hill MFE, Weber IP, Viscomi C, Zhao C, et al. Niche stiffness underlies the ageing of central nervous system progenitor cells. Nature. 2019;573:130–4.
Atcha H, Jairaman A, Holt JR, Meli VS, Nagalla RR, Veerasubramanian PK, et al. Mechanically activated ion channel Piezo1 modulates macrophage polarization and stiffness sensing. Nat Commun. 2021;12:3256.
He J, Fang B, Shan S, **e Y, Wang C, Zhang Y, et al. Mechanical stretch promotes hypertrophic scar formation through mechanically activated cation channel Piezo1. Cell Death Dis. 2021;12:226.
Li M, Zhang X, Wang M, Wang Y, Qian J, **ng X, et al. Activation of Piezo1 contributes to matrix stiffness-induced angiogenesis in hepatocellular carcinoma. Cancer Commun. 2022;42:1162–84.
Laurent P, Allard B, Manicki P, Jolivel V, Levionnois E, Jeljeli M, et al. TGFβ promotes low IL10-producing ILC2 with profibrotic ability involved in skin fibrosis in systemic sclerosis. Ann Rheum Dis. 2021;80:1594–603.
Mor A, Segal Salto M, Katav A, Barashi N, Edelshtein V, Manetti M, et al. Blockade of CCL24 with a monoclonal antibody ameliorates experimental dermal and pulmonary fibrosis. Ann Rheum Dis. 2019;78:1260–8.
Wu X, Hu J, Li G, Li Y, Li Y, Zhang J, et al. Biomechanical stress regulates mammalian tooth replacement via the integrin β1-RUNX2-Wnt pathway. EMBO J. 2020;39:e102374.
Zhou T, Gao B, Fan Y, Liu Y, Feng S, Cong Q, et al. Piezo1/2 mediate mechanotransduction essential for bone formation through concerted activation of NFAT-YAP1-ß-catenin. eLife. 2020;9:e52779.
Greuter T, Yaqoob U, Gan C, Jalan-Sakrikar N, Kostallari E, Lu J, et al. Mechanotransduction-induced glycolysis epigenetically regulates a CXCL1-dominant angiocrine signaling program in liver sinusoidal endothelial cells in vitro and in vivo. J Hepatol. 2022;77:723–34.
Niu L, Cheng B, Huang G, Nan K, Han S, Ren H, et al. A positive mechanobiological feedback loop controls bistable switching of cardiac fibroblast phenotype. Cell Discov. 2022;8:84.
Wu JJ, Sun ZL, Liu SY, Chen ZH, Yuan ZD, Zou ML, et al. The ASIC3-M-CSF-M2 macrophage-positive feedback loop modulates fibroblast-to-myofibroblast differentiation in skin fibrosis pathogenesis. Cell Death Dis. 2022;13:527.
Fang XZ, Li M, Wang YX, Zhang P, Sun MM, Xu JX, et al. Mechanosensitive ion channel Piezo1 mediates mechanical ventilation-exacerbated ARDS-associated pulmonary fibrosis. J Adv Res. 2022;53:175–86.
Liu L, Yu H, Zhao H, Wu Z, Long Y, Zhang J, et al. Matrix-transmitted paratensile signaling enables myofibroblast-fibroblast cross talk in fibrosis expansion. Proc Natl Acad Sci USA. 2020;117:10832–8.
**e L, Wang X, Ma Y, Ma H, Shen J, Chen J, et al. Piezo1 (piezo-type mechanosensitive ion channel component 1)-mediated mechanosensation in macrophages impairs perfusion recovery after hindlimb ischemia in mice. Arteriosc Thromb Vasc Biol. 2023;43:504–18.
Wang B, Ke W, Wang K, Li G, Ma L, Lu S, et al. Mechanosensitive ion channel piezo1 activated by matrix stiffness regulates oxidative stress-induced senescence and apoptosis in human intervertebral disc degeneration. Oxid Med Cell Longev. 2021;2021:8884922.
Sun Y, Liu J, Xu Z, Lin X, Zhang X, Li L, et al. Matrix stiffness regulates myocardial differentiation of human umbilical cord mesenchymal stem cells. Aging. 2020;13:2231–50.
Henderson NC, Rieder F, Wynn TA. Fibrosis: from mechanisms to medicines. Nature. 2020;587:555–66.
Wang S, Cao S, Arhatte M, Li D, Shi Y, Kurz S, et al. Adipocyte Piezo1 mediates obesogenic adipogenesis through the FGF1/FGFR1 signaling pathway in mice. Nat Commun. 2020;11:2303.
Hirata Y, Nomura K, Kato D, Tachibana Y, Niikura T, Uchiyama K, et al. A Piezo1/KLF15/IL-6 axis mediates immobilization-induced muscle atrophy. J Clin Investig. 2022;132:1–13.
**e Y, Chen D, Jiang K, Song L, Qian N, Du Y, et al. Hair shaft miniaturization causes stem cell depletion through mechanosensory signals mediated by a Piezo1-calcium-TNF-α axis. Cell Stem cell. 2022;29:70–85.e6.
Deng R, Li C, Wang X, Chang L, Ni S, Zhang W, et al. Periosteal CD68(+) F4/80(+) macrophages are mechanosensitive for cortical bone formation by secretion and activation of TGF-β1. Adv Sci. 2022;9:e2103343.
Forssmann U, Uguccioni M, Loetscher P, Dahinden CA, Langen H, Thelen M, et al. Eotaxin-2, a novel CC chemokine that is selective for the chemokine receptor CCR3, and acts like eotaxin on human eosinophil and basophil leukocytes. J Exp Med. 1997;185:2171–6.
Gaspar K, Kukova G, Bunemann E, Buhren BA, Sonkoly E, Szollosi AG, et al. The chemokine receptor CCR3 participates in tissue remodeling during atopic skin inflammation. J Dermatol Sci. 2013;71:12–21.
Heiman AS, Abonyo BO, Darling-Reed SF, Alexander MS. Cytokine-stimulated human lung alveolar epithelial cells release eotaxin-2 (CCL24) and eotaxin-3 (CCL26). J Interferon Cytokine Res : Off J Int Soc Interferon Cytokine Res. 2005;25:82–91.
Kohan M, Puxeddu I, Reich R, Levi-Schaffer F, Berkman N. Eotaxin-2/CCL24 and eotaxin-3/CCL26 exert differential profibrogenic effects on human lung fibroblasts. Ann Allergy Asthma Immunol : Off Publ Am Coll Allergy, Asthma, Immunol 2010;104:66–72.
Solis AG, Bielecki P, Steach HR, Sharma L, Harman CCD, Yun S, et al. Mechanosensation of cyclical force by PIEZO1 is essential for innate immunity. Nature. 2019;573:69–74.
Baratchi S, Zaldivia MTK, Wallert M, Loseff-Silver J, Al-Aryahi S, Zamani J, et al. Transcatheter aortic valve implantation represents an anti-inflammatory therapy via reduction of shear stress-induced, piezo-1-mediated monocyte activation. Circulation. 2020;142:1092–105.
Wong TY, Juang WC, Tsai CT, Tseng CJ, Lee WH, Chang SN, et al. Mechanical stretching simulates cardiac physiology and pathology through mechanosensor Piezo1. J Clin Med. 2018;7:410.
Kahn M. Can we safely target the WNT pathway? Nat Rev Drug Discov. 2014;13:513–32.
Wang X, Zou Y, Chen Z, Li Y, Pan L, Wang Y, et al. Low-density lipoprotein receptor-related protein 6 regulates cardiomyocyte-derived paracrine signaling to ameliorate cardiac fibrosis. Theranostics. 2021;11:1249–68.
Zou Y, Pan L, Shen Y, Wang X, Huang C, Wang H, et al. Cardiac Wnt5a and Wnt11 promote fibrosis by the crosstalk of FZD5 and EGFR signaling under pressure overload. Cell Death Dis. 2021;12:877.
Liu T, Gonzalez De Los Santos F, Hirsch M, Wu Z, Phan SH. Noncanonical Wnt signaling promotes myofibroblast differentiation in pulmonary fibrosis. Am J Respir Cell Mol Biol. 2021;65:489–99.
Yin C, Ye Z, Wu J, Huang C, Pan L, Ding H, et al. Elevated Wnt2 and Wnt4 activate NF-κB signaling to promote cardiac fibrosis by cooperation of Fzd4/2 and LRP6 following myocardial infarction. EBioMedicine. 2021;74:103745.
Bayle J, Fitch J, Jacobsen K, Kumar R, Lafyatis R, Lemaire R. Increased expression of Wnt2 and SFRP4 in Tsk mouse skin: role of Wnt signaling in altered dermal fibrillin deposition and systemic sclerosis. J Investig Dermatol. 2008;128:871–81.
Li Y, Chen M, Hu J, Sheng R, Lin Q, He X, et al. Volumetric compression induces intracellular crowding to control intestinal organoid growth via Wnt/β-catenin signaling. Cell Stem Cell. 2021;28:63–78.e7.
Przybyla L, Lakins JN, Weaver VM. Tissue mechanics orchestrate wnt-dependent human embryonic stem cell differentiation. Cell Stem Cell. 2016;19:462–75.
Karin M, Clevers H. Reparative inflammation takes charge of tissue regeneration. Nature. 2016;529:307–15.
Wellenstein MD, Coffelt SB, Duits DEM, van Miltenburg MH, Slagter M, de Rink I, et al. Loss of p53 triggers WNT-dependent systemic inflammation to drive breast cancer metastasis. Nature. 2019;572:538–42.
Wong DWL, Yiu WH, Chan KW, Li Y, Li B, Lok SWY, et al. Activated renal tubular Wnt/β-catenin signaling triggers renal inflammation during overload proteinuria. Kidney Int. 2018;93:1367–83.
Kotterman MA, Schaffer DV. Engineering adeno-associated viruses for clinical gene therapy. Nat Rev Genet. 2014;15:445–51.
Lugin ML, Lee RT, Kwon YJ. Synthetically engineered adeno-associated virus for efficient, safe, and versatile gene therapy applications. ACS Nano. 2020;14:14262–83.
Kurita M, Araoka T, Hishida T, O’Keefe DD, Takahashi Y, Sakamoto A, et al. In vivo reprogramming of wound-resident cells generates skin epithelial tissue. Nature. 2018;561:243–7.
Galeano M, Deodato B, Altavilla D, Cucinotta D, Arsic N, Marini H, et al. Adeno-associated viral vector-mediated human vascular endothelial growth factor gene transfer stimulates angiogenesis and wound healing in the genetically diabetic mouse. Diabetologia. 2003;46:546–55.
Shi H, Wang X, Li F, Gerlach BD, Yurdagul A Jr, Moore MP, et al. CD47-SIRPα axis blockade in NASH promotes necroptotic hepatocyte clearance by liver macrophages and decreases hepatic fibrosis. Sci Transl Med. 2022;14:eabp8309.
Dong F, Jiang S, Li J, Wang Y, Zhu L, Huang Y, et al. The histone demethylase KDM4D promotes hepatic fibrogenesis by modulating Toll-like receptor 4 signaling pathway. EBioMedicine. 2019;39:472–83.
Chen H, Cai J, Wang J, Qiu Y, Jiang C, Wang Y, et al. Targeting Nestin(+) hepatic stellate cells ameliorates liver fibrosis by facilitating TβRI degradation. J Hepatol. 2021;74:1176–87.
Gupta S, Fink MK, Kempuraj D, Sinha NR, Martin LM, Keele LM, et al. Corneal fibrosis abrogation by a localized AAV-mediated inhibitor of differentiation 3 (Id3) gene therapy in rabbit eyes in vivo. J Am Soc Gene Ther. 2022;30:3257–69.
He J, Fang B, Shan S, Li Q. Mechanical stiffness promotes skin fibrosis through Piezo1-mediated arginine and proline metabolism. Cell Death Discov. 2023;9:354.
Ho YY, Lagares D, Tager AM, Kapoor M. Fibrosis–a lethal component of systemic sclerosis. Nat Rev Rheumatol. 2014;10:390–402.
Achterberg VF, Buscemi L, Diekmann H, Smith-Clerc J, Schwengler H, Meister JJ, et al. The nano-scale mechanical properties of the extracellular matrix regulate dermal fibroblast function. J Investig Dermatol. 2014;134:1862–72.
Love MI, Huber W, Anders S. Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2. Genome Biol. 2014;15:550.
Funding
This work was supported by grants from the National Natural Science Foundation of China (82102343, 82102327) and Shanghai Clinical Research Center of Plastic and Reconstructive Surgery supported by the Science and Technology Commission of Shanghai Municipality (Grant No. 22MC1940300).
Author information
Authors and Affiliations
Contributions
Conceptualization, SZS, and QFL; investigation, JHH; writing—original draft, JHH and XWC; writing–review & editing, BF and QFL; funding acquisition, BF and SZS.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Edited by Eleonora Candi
Supplementary information
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 license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license 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 license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
He, J., Cheng, X., Fang, B. et al. Mechanical stiffness promotes skin fibrosis via Piezo1-Wnt2/Wnt11-CCL24 positive feedback loop. Cell Death Dis 15, 84 (2024). https://doi.org/10.1038/s41419-024-06466-3
Received:
Revised:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41419-024-06466-3
- Springer Nature Limited