Endoplasmic reticulum stress in the kidney

Endoplasmic reticulum (ER) stress is involved in a wide range of pathological circumstances including neurodegenerative disorders, diabetes mellitus, ischemic injury, cancers, atherosclerosis, inflammation, infection, toxicity of chemicals and metals, and psychotic diseases. ER stress is also involved in some physiological events including development of particular cell types. A number of pathophysiological triggers cause accumulation of unfolded proteins in the ER, i.e., ER stress. In response to accumulation of unfolded/misfolded proteins, cells adapt themselves to the stress conditions via a coordinated adaptive program, the unfolded protein response (UPR). UPR is a double-edged sword. It induces both prosurvival and proapoptotic signaling. It also triggers both proinflammatory and anti-inflammatory signals. In this review, I summarize current knowledge on putative, pathophysiological roles of ER stress in the kidney.     

Trehalose promotes functional recovery of keratinocytes under oxidative stress and wound healing via ATG5/ATG7

Wounds are in a stressed state, which precludes healing. Trehalose is a stress metabolite that protects cells under stress. Here, we explored whether trehalose reduces stress-induced wound tissue damage. A stress model was prepared by exposing human keratinocytes to hydrogen peroxide (H₂O₂), followed by trehalose treatment. Trehalose effects on expression of the autophagy-related proteins ATG5 and ATG7 and cell proliferation and migration were evaluated. For in vivo verification, a wound model was established in Sprague–Dawley rats, to measure the effects of trehalose wound-healing rate and reactive oxygen species (ROS) content. Histological changes during wound healing and trehalose's effects on ATG5 and ATG7 expression, necrosis, and apoptosis were examined·H₂O₂ stress increased ATG5 and ATG7 expression in vitro, but this was insufficient to prevent stress-induced damage. Trehalose further increased ATG5/ATG7 levels, which restored proliferation and increased migration by depolymerizing the cytoskeleton. However, trehalose did not exert these effects after ATG5 and ATG7 knockout. In vivo, the ROS content was higher in the wound tissue than in normal skin. Trehalose increased ATG5/ATG7 expression in wound tissue keratinocytes, reduced necrosis, depolymerized the cytoskeleton, and promoted cell migration, thereby promoting wound healing.     

Endoplasmic reticulum stress and the ER mitochondrial calcium cycle in amyotrophic lateral sclerosis

The endoplasmic reticulum (ER) is a multifunctional organelle involved in protein synthesis, processing and folding, in intracellular transport and calcium signalling. ER stress can be triggered by depletion of ER calcium content and the accumulation of un- and mis-folded proteins, and relays stress signals to the ER mitochondria calcium cycle (ERMCC) and to the nucleus and protein translation machinery. The ensuing unfolded protein response (UPR) helps to cope with ER stress. Total protein synthesis is inhibited to keep protein load low, while the synthesis of ER chaperones, which assist protein folding, is induced. If cell integrity cannot be restored, signal cascades mediating cell death are activated. This review focuses on the role of ER stress and the UPR in the pathology of amyotrophic lateral sclerosis (ALS). The triggers for ER stress are as yet unclear, but induction of UPR sensor proteins, up-regulation of chaperones and induction of cell death proteins have been described in human post mortem ALS tissue and in mutant superoxide dismutase-1 (SOD1) expressing models of ALS. TDP-43 and VAPB seem to be involved in UPR signalling as well. Recent reports raise hope that UPR sensor proteins become effective therapeutic targets in the treatment of ALS.     

The importance of both fibroblasts and keratinocytes in a bilayered living cellular construct used in wound healing

Cross talk between fibroblasts and keratinocytes, which maintains skin homeostasis, is disrupted in chronic wounds. For venous leg ulcers and diabetic foot ulcers, a bilayered living cellular construct (BLCC), containing both fibroblasts and keratinocytes that participate in cross talk, is a safe and effective product in healing chronic wounds. To show the importance of both cell types in BLCC, constructs were generated containing only fibroblasts or only keratinocytes and compared directly to BLCC via histology, mechanical testing, gene/protein analysis, and angiogenesis assays. BLCC contained a fully differentiated epithelium and showed greater tensile strength compared with one‐cell‐type constructs, most likely due to formation of intact basement membrane and well‐established stratum corneum in BLCC. Furthermore, expression of important wound healing genes, cytokines, and growth factors was modulated by the cells in BLCC compared with constructs containing only one cell type. Finally, conditioned medium from BLCC promoted greater endothelial network formation compared with media from one‐cell‐type constructs. Overall, this study characterized a commercially available wound healing product and showed that the presence of both fibroblasts and keratinocytes in BLCC contributed to epithelial stratification, greater tensile strength, modulation of cytokine and growth factor expression, and increased angiogenic properties compared with constructs containing fibroblasts or keratinocytes alone.     

Exogenous CLASP2 protein treatment enhances wound healing in vitro and in vivo

Proliferative and migratory abilities of fibroblasts are essential for wound healing at the skin surface. Cytoplasmic linker‐associated protein‐2 (CLASP2) was originally found to interact with cytoplasmic linker protein (CLIP)‐170. CLASP2 plays an important role in microtubule stabilization and the microtubule‐stabilizing activity of CLASP2 depends on its interactions with end binding (EB)‐1 and CLIP‐170. Although the microtubule‐stabilizing role of CLASP2 is well established, the effects of CLASP2 on the migration and proliferation of fibroblasts remain unclear in the context of wound healing. Therefore, we tested the utilization of CLASP2 as a directly applied protein drug to improve wound healing by promoting the migration of effector cells, including skin fibroblasts, to the site of repair or injury using an in vivo excisional wound mouse model and in vitro Hs27 skin fibroblast model. Epidermal growth factor, which is a recognized contributor to cell proliferation and migration, was used as positive control. In vitro and in vivo, CLASP2 treatment significantly enhanced cell migration and accelerated wound closure. Furthermore, in vivo, the CLASP2‐treated animal group displayed enhanced epidermal repair and collagen deposition. Next, we studied the mechanism of CLASP2 for wound healing. Increasing the abundance of intracellular free CLASP2 in skin fibroblasts by supplying exogenous CLASP2 seemed to stabilize microtubules through an interaction between CLASP2 and CLIP‐170, as well as EB1. Exogenous CLASP2 also showed direct binding with IQGAP1, increasing both cyclic adenosine monophosphate activity and phosphorylation of glycogen synthase kinase 3β, which in turn reinstated the binding between free CLASP2 and IQGAP1. In summary, exogenous CLASP2 increased Hs27 skin fibroblast migration by interacting with IQGAP1 and other cytoskeletal linker proteins, such as CLIP‐170 and EB1. Our results strongly suggest that CLASP2 can be developed in wound healing drugs for skin repair and/or regenerating cosmetic products.     

Cell surface engineering using glycosylphosphatidylinositol anchored tissue inhibitor of matrix metalloproteinase‐1 stimulates cutaneous wound healing

The balance between matrix metalloproteinases and their endogenous tissue inhibitors (TIMPs) is an important component in effective wound healing. The biologic action of these proteins is linked in part to the stoichiometry of TIMP/matrix metalloproteinases/surface protein interactions. We recently described the effect of a glycosylphosphatidylinositol (GPI) anchored version of TIMP‐1 on dermal fibroblast biology. Here, cell proliferation assays, in vitro wound healing, electrical wound, and impedance measurements were used to characterize effects of TIMP‐1‐GPI treatment on primary human epidermal keratinocytes. TIMP‐1‐GPI stimulated keratinocyte proliferation, as well as mobilization and migration. In parallel, it suppressed the migration and matrix secretion of dermal myofibroblasts, and reduced their secretion of active TGF‐β1. Topical application of TIMP‐1‐GPI in an in vivo excisional wound model increased the rate of wound healing. The agent positively influenced different aspects of wound healing depending on the cell type studied. TIMP‐1‐GPI counters potential negative effects of overactive myofibroblasts and enhances the mobilization and proliferation of keratinocytes essential for effective wound healing. The application of TIMP‐1‐GPI represents a novel and practical clinical solution for facilitating healing of difficult wounds.     

Extracellular matrix/stromal vascular fraction gel conditioned medium accelerates wound healing in a murine model

Conditioned medium (CM) is a new treatment modality in regenerative medicine and has shown a successful outcome in wound healing. We recently introduced extracellular matrix/stromal vascular fraction gel (ECM/SVF‐gel), an adipose‐derived stem cell and adipose native extracellular matrix‐enriched product for cytotherapy. This study aimed to evaluate the effect of CM from ECM/SVF‐gel (Gel‐CM) on wound healing compared with the conventional CM from adipose tissue (Adi‐CM) and stem cell (SVF‐CM). In vitro wound healing effect of three CMs on keratinocytes and fibroblasts was evaluated in terms of proliferation property, migratory property, and extracellular matrix production. In vivo, two full‐thickness wounds were created on the back of each mice. The wounds were randomly divided to receive Gel‐CM, Adi‐CM, SVF‐CM, and PBS injection. Histologic observations and collagen content of wound skin were made. Growth factors concentration in three CMs was further quantified. In vitro, Gel‐CM promoted the proliferation and migration of keratinocytes and fibroblasts and enhanced collagen I synthesis in fibroblasts compared to Adi‐CM and SVF‐CM. In vivo, wound closure was faster, and dermal and epidermal regeneration was improved in the Gel‐CM‐treated mice compared to that in Adi‐CM and SVF‐CM‐treated mice. Moreover, The growth factors concentration (i.e., vascular endothelial growth factor, basic fibroblast growth factor, hepatocyte growth factor, and transforming growth factor‐β) in Gel‐CM were significantly higher than those in Adi‐CM and SVF‐CM. Gel‐CM generated under serum free conditions significantly enhanced wound healing effect compared to Adi‐CM and SVF‐CM by accelerating cell proliferation, migration, and production of ECM. This improved trophic effect may be attributed to the higher growth factors concentration in Gel‐CM. Gel‐CM shows potential as a novel and promising alternative to skin wound healing treatment. But limitations include the safety and immunogenicity studies of Gel‐CM still remain to be clearly clarified and more data on mechanism study are needed.     

Different wound healing properties of dermis,adipose, and gingiva mesenchymal stromal cells

Oral wounds heal faster and with better scar quality than skin wounds. Deep skin wounds where adipose tissue is exposed, have a greater risk of forming hypertrophic scars. Differences in wound healing and final scar quality might be related to differences in mesenchymal stromal cells (MSC) and their ability to respond to intrinsic (autocrine) and extrinsic signals, such as human salivary histatin, epidermal growth factor, and transforming growth factor beta1. Dermis‐, adipose‐, and gingiva‐derived MSC were compared for their regenerative potential with regards to proliferation, migration, and matrix contraction. Proliferation was assessed by cell counting and migration using a scratch wound assay. Matrix contraction and alpha smooth muscle actin was assessed in MSC populated collagen gels, and also in skin and gingival full thickness tissue engineered equivalents (reconstructed epithelium on MSC populated matrix). Compared to skin‐derived MSC, gingiva MSC showed greater proliferation and migration capacity, and less matrix contraction in full thickness tissue equivalents, which may partly explain the superior oral wound healing. Epidermal keratinocytes were required for enhanced adipose MSC matrix contraction and alpha smooth muscle actin expression, and may therefore contribute to adverse scarring in deep cutaneous wounds. Histatin enhanced migration without influencing proliferation or matrix contraction in all three MSC, indicating that salivary peptides may have a beneficial effect on wound closure in general. Transforming growth factor beta1 enhanced contraction and alpha smooth muscle actin expression in all three MSC types when incorporated into collagen gels. Understanding the mechanisms responsible for the superior oral wound healing will aid us to develop advanced strategies for optimal skin regeneration, wound healing and scar formation.     

An in vitro wound healing model for evaluation of dermal substitutes

Reepithelialization of skin wounds is essential to restore barrier function and prevent infection. This process requires coordination of keratinocyte proliferation, migration, and differentiation, which may be impeded by various extrinsic and host‐dependent factors. Deep, full‐thickness wounds, e.g., burns, are often grafted with dermal matrices before transplantation of split‐skin grafts. These dermal matrices need to be integrated in the host skin and serve as a substrate for neoepidermis formation. Systematic preclinical analysis of keratinocyte migration on established and experimental matrices has been hampered by the lack of suitable in vitro model systems. Here, we developed an in vitro full‐thickness wound healing model in tissue‐engineered human skin that allowed analysis of the reepithelialization process across different grafted dermal substitutes. We observed strong differences between porous and nonporous matrices, the latter being superior for reepithelialization. This finding was corroborated in rodent wound healing models. The model was optimized using lentivirus‐transduced keratinocytes expressing enhanced green fluorescent protein and by the addition of human blood, which accelerated keratinocyte migration underneath the clot. Our model shows great potential for preclinical evaluation of tissue‐engineered dermal substitutes in a medium‐throughput format, thereby obviating the use of large numbers of experimental animals.     

Lesional skin in vitiligo exhibits delayed in vivo reepithelialization compared to the nonlesional skin

Vitiligo, a common skin disorder, is characterized by the loss of functional melanocytes resulting in the depigmentation of skin. Previous studies have demonstrated molecular and architectural alterations in the epidermal keratinocytes upon loss of melanocytes. The physiological implications of these “altered” keratinocytes are yet not known. We investigated the wound healing efficiency of lesional vs nonlesional skin in 12 subjects with stable nonsegmental vitiligo using histological and ultrastructural evaluation of partial‐thickness wounds. The wounds were examined 12 days postinjury, coinciding with the reepithelialization phase of healing marked primarily by keratinocyte migration and proliferation. This study demonstrated a significant difference in the reepithelialization potential between the lesional and nonlesional skin. While all 12 nonlesional wounds demonstrated considerable neoepidermis formation on the 12th day post wound, only four of the corresponding lesional samples showed comparable reepithelialization; the rest remaining in the inflammatory phase. Ultrastructural studies using transmission electron microscopy as well as immunohistochemical staining revealed a reduced number of desmosomes, shorter keratin tonofilaments and an increase in myofibroblast population in the dermis of lesional reepithelialized tissue compared to the nonlesional reepithelialized samples. This study implicates gross functional perturbations in the lesional skin during physiological wound healing in vitiligo, suggesting that the breakdown of keratinocyte‐melanocyte network results in delayed wound repair kinetics in the lesional skin when compared to patient‐matched nonlesional skin.     

Endoplasmic reticulum stress and its effects on renal tubular cells apoptosis in ischemic acute kidney injury

Ischemia is the most frequent cause of acute kidney injury (AKI), which is characterized by apoptosis of renal tubular cell. A common result of ischemia in AKI is dysfunction of endoplasmic reticulum (ER), which causes the protein-folding capacity to lag behind the protein-folding load. The abundance of misfolded proteins stressed the ER and results in induction of the unfolded protein response (UPR). While the UPR is an adaptive response, over time it can result in apoptosis when cells are unable to recover quickly. Recent research suggests that ER stress is a major factor in renal tubular cell apoptosis resulting from ischemic AKI. Thus, ER stress may be an important new progression factor in the pathology of ischemic AKI. In this article, we review UPR signaling, describe pathology and pathophysiology mechanisms of ischemic AKI, and highlight the dual function of ER stress on renal tubular cell apoptosis.     

Integrin α3 subunit regulates events linked to epithelial repair,including keratinocyte migration and protein expression

Two integrins, α3β1 and α6β4, are high‐affinity receptors for laminin 332, the major laminin isoform of the dermal–epidermal junction, although they are thought to have different functions. Biological and genetic studies have firmly established that the α6β4 integrin is indispensable for the stable anchorage of the epidermis to the underlying dermis. In contrast, the α3β1 integrin is thought to be important for cell migration, although the issue is controversial, and both positive and negative effects have been reported. To address the function of α3β1 integrin, we used small interfering RNA to down‐regulate the α3 subunit in human keratinocytes. The resulting phenotype indicates that lack of α3β1 integrin compromises intercellular adhesion and collective migration, while it enhances single cell migration with a concomitant increase of both focal adhesion kinase and extracellular signal‐regulated kinase. In addition, down‐regulation of integrin α3 subunit results in an increased expression of fibronectin and precursor laminin 332, two extracellular matrix proteins known to be up‐regulated during wound healing. Thus, down‐regulation of α3β1 integrin recapitulates crucial events governing keratinocyte migration associated with wound healing and tissue repair.     

The effects of caffeine on wound healing

The purine alkaloid caffeine is a major component of many beverages such as coffee and tea. Caffeine and its metabolites theobromine and xanthine have been shown to have antioxidant properties. Caffeine can also act as adenosine‐receptor antagonist. Although it has been shown that adenosine and antioxidants promote wound healing, the effect of caffeine on wound healing is currently unknown. To investigate the effects of caffeine on processes involved in epithelialisation, we used primary human keratinocytes, HaCaT cell line and ex vivo model of human skin. First, we tested the effects of caffeine on cell proliferation, differentiation, adhesion and migration, processes essential for normal wound epithelialisation and closure. We used 3‐(4,5‐dimethylthiazol‐2‐yl)‐2,5‐diphenyl tetrazolium bromide (MTT) proliferation assay to test the effects of seven different caffeine doses ranging from 0·1 to 5 mM. We found that caffeine restricted cell proliferation of keratinocytes in a dose‐dependent manner. Furthermore, scratch wound assays performed on keratinocyte monolayers indicated dose‐dependent delays in cell migration. Interestingly, adhesion and differentiation remained unaffected in monolayer cultures treated with various doses of caffeine. Using a human ex vivo wound healing model, we tested topical application of caffeine and found that it impedes epithelialisation, confirming in vitro data. We conclude that caffeine, which is known to have antioxidant properties, impedes keratinocyte proliferation and migration, suggesting that it may have an inhibitory effect on wound healing and epithelialisation. Therefore, our findings are more in support of a role for caffeine as adenosine‐receptor antagonist that would negate the effect of adenosine in promoting wound healing.     

Level of Fibronectin mRNA Is Markedly Increased in Human Chronic Wounds

BACKGROUND: Acute wound healing has been extensively investigated over the years, however, little is known about possible healing defects in chronic wounds. Fibronectin (FN) plays a critical role in different phases of wound healing and has been demonstrated to be degraded in chronic wounds by proteases. Fibroblasts cultured from chronic leg ulcers showed a higher level of FN compared to normal fibroblasts. OBJECTIVE: We explored whether the increase in FN protein in chronic wounds is due to increased FN mRNA. In addition, the level of alpha5beta1 integrin FN cell surface receptor was also examined. METHOD: Skin biopsies were taken from normal skin within a few hours of Mohs surgery and from the edge of chronic venous leg ulcers. In situ hybridization was performed to determine the level of FN mRNA. The level of integrin alpha5beta1 was determined by immunohistochemistry. RESULTS: The level of FN mRNA in normal skin and acute wounds was undetectable. In contrast, FN mRNA was heavily induced throughout the dermis of chronic wounds. Immunostaining using a monoclonal antibody against the alpha5 subunit of integrin revealed that chronic wounds and normal skin showed undetectable levels of alpha5beta1 integrin. A large induction of alpha5 was observed in acute wounds. CONCLUSION: For reepithelization to occur, epidermal keratinocytes need to migrate over the wound surface, a process requiring an interaction between FN and its cell surface receptor integrin alpha5beta1. These findings suggest that although FN mRNA is increased in chronic wounds, lack of FN cell surface receptor may prevent migration of epidermal keratinocytes in chronic wounds.     

基质金属蛋白酶—1在表皮修复中的生物学作用

目的 阐明有关基质金属蛋白酶－1（MMP－1）在皮肤损伤后,表皮修复过程中的作用。方法 回顾近年来有关MMP－1在皮肤损伤修复中的作用及研究进展,总结其在上皮化局部微小环境内的表达及细胞分子生物学效应。结果 皮肤损伤信号直接引发表皮细胞于特定的部位及时间表达MMP－1;MMP－1通过特异性分解创面基质胶原蛋白,促进表皮细胞的增殖及迁移,由此影响表皮损伤创面的愈合结果。结论 皮肤损伤后表皮细胞表达MMP－1与创面重新上皮化直接相关。     

Coacervate delivery of HB‐EGF accelerates healing of type 2 diabetic wounds

Chronic wounds such as diabetic ulcers pose a significant challenge as a number of underlying deficiencies prevent natural healing. In pursuit of a regenerative wound therapy, we developed a heparin‐based coacervate delivery system that provides controlled release of heparin‐binding epidermal growth factor (EGF)‐like growth factor (HB‐EGF) within the wound bed. In this study, we used a polygenic type 2 diabetic mouse model to evaluate the capacity of HB‐EGF coacervate to overcome the deficiencies of diabetic wound healing. In full‐thickness excisional wounds on NONcNZO10 diabetic mice, HB‐EGF coacervate enhanced the proliferation and migration of epidermal keratinocytes, leading to accelerated epithelialization. Furthermore, increased collagen deposition within the wound bed led to faster wound contraction and greater wound vascularization. Additionally, in vitro assays demonstrated that HB‐EGF released from the coacervate successfully increased migration of diabetic human keratinocytes. The multifunctional role of HB‐EGF in the healing process and its enhanced efficacy when delivered by the coacervate make it a promising therapy for diabetic wounds.