Granzyme B degrades extracellular matrix and contributes to delayed wound closure in apolipoprotein E knockout mice

Chronic inflammation and excessive protease activity have a major role in the persistence of non-healing wounds. Granzyme B (GzmB) is a serine protease expressed during chronic inflammation that, in conjunction with perforin, has a well-established role in initiating apoptotic cell death. GzmB is also capable of acting extracellularly, independent of perforin and can degrade several extracellular matrix (ECM) proteins that are critical during wound healing. We used apolipoprotein E (ApoE) knockout (AKO) mice as a novel model of chronic inflammation and impaired wound healing to investigate the role of GzmB in chronic wounds. Wild-type and AKO mice were grown to 7 weeks (young) or 37 weeks (old) of age on a regular chow or high-fat diet (HFD), given a 1-cm diameter full thickness wound on their mid dorsum and allowed to heal for 16 days. Old AKO mice fed a HFD exhibited reduced wound closure, delayed contraction, chronic inflammation and altered ECM remodeling. Conversely, GzmB/ApoE double knockout mice displayed improved wound closure and contraction rates. In addition, murine GzmB was found to degrade both fibronectin and vitronectin derived from healthy mouse granulation tissue. In addition, GzmB-mediated degradation of fibronectin generated a fragment similar in size to that observed in non-healing mouse wounds. These results provide the first direct evidence that GzmB contributes to chronic wound healing in part through degradation of ECM.     

Granzyme B in skin inflammation and disease

Granzyme B (GzmB) is a serine protease emerging as an important mediator of skin injury, inflammation and repair. Found at low levels in healthy skin, GzmB is dramatically elevated in chronic disease and inflammatory skin disorders, including diabetic ulcers, hypertrophic scarring, autoimmune skin disorders, cutaneous leishmaniasis and aging skin. Traditionally known for its pro-apoptotic function, the role of GzmB in disease has been redefined due to the discovery of additional activities involving the cleavage of extracellular matrix proteins, epithelial barrier disruption, fibrosis, vascular permeability, anoikis, inflammation and autoimmunity. In addition to the accumulation of GzmB⁺ cells in diseased tissue, and critical to the mechanistic redefinition, is the realization that GzmB often accumulates in the extracellular milieu, retains its activity in plasma, and is expressed by both immune and non-immune cells that may or may not express perforin, the pore-forming protein required for GzmB internalization into target cells. As GzmB is not normally found in the extracellular milieu, and does not appear to be regulated, GzmB-mediated proteolysis can impact processes such as tissue remodelling, barrier function, autoantigen generation and angiogenesis. The present review will summarize and critically examine the current knowledge regarding GzmB in inflammatory skin disease, providing an overview of both apoptotic and extracellular mechanisms, but with a focus on the extracellular roles of GzmB in skin health and disease.     

Serpina3n accelerates tissue repair in a diabetic mouse model of delayed wound healing

Chronic, non-healing wounds are a major complication of diabetes and are characterized by chronic inflammation and excessive protease activity. Although once thought to function primarily as a pro-apoptotic serine protease, granzyme B (GzmB) can also accumulate in the extracellular matrix (ECM) during chronic inflammation and cleave ECM proteins that are essential for proper wound healing, including fibronectin. We hypothesized that GzmB contributes to the pathogenesis of impaired diabetic wound healing through excessive ECM degradation. In the present study, the murine serine protease inhibitor, serpina3n (SA3N), was administered to excisional wounds created on the dorsum of genetically induced type-II diabetic mice. Wound closure was monitored and skin wound samples were collected for analyses. Wound closure, including both re-epithelialization and contraction, were significantly increased in SA3N-treated wounds. Histological and immunohistochemical analyses of SA3N-treated wounds revealed a more mature, proliferative granulation tissue phenotype as indicated by increased cell proliferation, vascularization, fibroblast maturation and differentiation, and collagen deposition. Skin homogenates from SA3N-treated wounds also exhibited greater levels of full-length intact fibronectin compared with that of vehicle wounds. In addition, GzmB-induced detachment of mouse embryonic fibroblasts correlated with a rounded and clustered phenotype that was prevented by SA3N. In summary, topical administration of SA3N accelerated wound healing. Our findings suggest that GzmB contributes to the pathogenesis of diabetic wound healing through the proteolytic cleavage of fibronectin that is essential for normal wound closure, and that SA3N promotes granulation tissue maturation and collagen deposition.Diabetic skin ulcers are non-healing, chronic wounds that pose a major health burden to society.¹ Up to a quarter of diabetic patients will develop these ulcers in their lifetime and as a result, nearly a fifth of these diabetic patients will require non-traumatic lower limb amputations.² Numerous advanced treatment options for the management of diabetic ulcers have been explored, including bioengineered skin substitutes, hyperbaric oxygen therapy and negative pressure dressings.^{3, 4, 5} However, they have largely been unsuccessful. As such, a combination of lifestyle modification, pressure off-loading, local surgical or larval debridement and infection control continue to be the standard recommended treatment strategy.⁶Wound healing is a complex process that involves overlapping and sequential phases involving haemostasis, inflammation, granulation tissue formation and tissue remodelling. For wounds to heal timely and properly, there must be a fine balance of interaction between various cell types, cytokines, growth factors, proteases and extracellular matrix (ECM) components. However, in diabetic patients, the normal continuum of wound healing is disrupted, and wounds enter a chronic, non-healing state characterized by persistent inflammation, enhanced proteolytic activity and impaired ECM deposition.⁷ The roles of various proteases, primarily matrix metalloproteinases (MMPs), have been extensively studied. Although MMPs were once believed to be the major culprits in impaired wound healing, it is now recognized that they are essential for normal wound healing by modulating inflammation, angiogenesis and tissue remodelling.^{8, 9, 10} Therefore, other proteases may also contribute to the pathogenesis of chronic wound healing.Granzyme B (GzmB) is a cytotoxic serine protease that is often viewed exclusively as a pro-apoptotic serine protease that is released from cytotoxic lymphocytes, along with the pore-forming, molecule perforin, to induce cell death.¹¹ However, because GzmB can be induced in other types of immune and non-immune cells that often do not express perforin and/or do not form immunological synapses with target cells, there is emerging evidence supporting the paradigm that GzmB can accumulate and function in the extracellular milieu.¹² In support, many ECM proteins are GzmB substrates and the consequences of such cleavage may be implicated in many diseases associated with aging and/or chronic inflammation such as abdominal aortic aneurysm (AAA), skin aging, atherosclerosis and wound healing using GzmB knockout mice.^{13, 14, 15, 16} Fibronectin is one such ECM glycoprotein that has an important role in cell attachment, differentiation and migration during wound healing and is cleaved by GzmB.¹⁷The serine protease inhibitors, also known as serpins, are the largest protease inhibitor super family and are divided into 16 clades.¹⁸ Serpina3n (SA3N), which is part of the SERPINA clade, is the mouse orthologue of the human anti-chymotrypsin (ACT) and has been identified as an inhibitor of both human and mouse GzmB in vitro.^{19, 20, 21} The human ACT is encoded by only one gene; however, extensive diversification and duplication in mice have resulted in 13 related serpina genes clustered at chromosome 12F1.¹⁹ Out of these, SA3N was identified to be the only extracellular inhibitor of GzmB.²¹ A previous study by our group had demonstrated efficacy for SA3N as an in vivo GzmB inhibitor in a murine model of AAA.²⁰The purpose of this study was to determine whether local inhibition of extracellular GzmB could accelerate wound closure in a genetically induced type-II diabetic mouse model of delayed wound healing. As many of the proteins in the ECM involved in wound healing are subject to cleavage by GzmB, we propose that SA3N accelerates wound healing by inhibiting protease-related ECM degradation.     

Solar Ultraviolet Irradiation Induces Decorin Degradation in Human Skin Likely via Neutrophil Elastase

Exposure of human skin to solar ultraviolet (UV) irradiation induces matrix metalloproteinase-1 (MMP-1) activity, which degrades type I collagen fibrils. Type I collagen is the most abundant protein in skin and constitutes the majority of skin connective tissue (dermis). Degradation of collagen fibrils impairs the structure and function of skin that characterize skin aging. Decorin is the predominant proteoglycan in human dermis. In model systems, decorin binds to and protects type I collagen fibrils from proteolytic degradation by enzymes such as MMP-1. Little is known regarding alterations of decorin in response to UV irradiation. We found that solar-simulated UV irradiation of human skin in vivo stimulated substantial decorin degradation, with kinetics similar to infiltration of polymorphonuclear (PMN) cells. Proteases that were released from isolated PMN cells degraded decorin in vitro. A highly selective inhibitor of neutrophil elastase blocked decorin breakdown by proteases released from PMN cells. Furthermore, purified neutrophil elastase cleaved decorin in vitro and generated fragments with similar molecular weights as those resulting from protease activity released from PMN cells, and as observed in UV-irradiated human skin. Cleavage of decorin by neutrophil elastase significantly augmented fragmentation of type I collagen fibrils by MMP-1. Taken together, these data indicate that PMN cell proteases, especially neutrophil elastase, degrade decorin, and this degradation renders collagen fibrils more susceptible to MMP-1 cleavage. These data identify decorin degradation and neutrophil elastase as potential therapeutic targets for mitigating sun exposure-induced collagen fibril degradation in human skin.     

Oxidative inhibition of receptor-type protein-tyrosine phosphatase kappa by ultraviolet irradiation activates epidermal growth factor receptor in human keratinocytes

Ultraviolet (UV) irradiation rapidly increases tyrosine phosphorylation (i.e. activates) of epidermal growth factor receptors (EGFR) in human skin. EGFR-dependent signaling pathways drive increased expression of matrix metalloproteinases, whose actions fragment collagen and elastin fibers, the primary structural protein components in skin connective tissue. Connective tissue fragmentation, which results from chronic exposure to solar UV irradiation, is a major determinant of premature skin aging (photoaging). UV irradiation generates reactive oxygen species, which readily react with conserved cysteine residues in the active site of protein-tyrosine phosphatases (PTP). We report here that EGFR activation by UV irradiation results from oxidative inhibition of receptor type PTP-kappa (RPTP-kappa). RPTP-kappa directly counters intrinsic EGFR tyrosine kinase activity, thereby maintaining EGFR in an inactive state. Reversible, oxidative inactivation of RPTP-kappa activity by UV irradiation shifts the kinase-phosphatase balance in favor of EGFR activation. These data delineate a novel mechanism of EGFR regulation and identify RPTP-kappa as a key molecular target for antioxidant protection against skin aging.     

Extracellular matrix production and regulation in micropatterned endothelial cells

Production and maintenance of extracellular matrix (ECM) is an essential aspect of endothelial cell (EC) function. ECM surfaces composed of collagen type IV and laminin support an atheroprotective endothelium, while fibronectin may encourage an atheroprone endothelium through inflammation or wound repair signaling. ECs maintain this underlying structure through regulation of protein production and degradation, yet the role of cytoskeletal alignment on this regulation is unknown. To examine the regulation and production of ECM by ECs with an atheroprotective phenotype, ECs were micropatterned onto lanes, which created an elongated EC morphology similar to that seen with unidirectional fluid shear stress application. Collagen IV and fibronectin protein production were measured as were gene expression of collagen IV, fibronectin, laminin, MMP2, MMP9, TIMP1, TIMP2, and TGF-β1. ECs were also treated with TNF to simulate an injury model. Micropattern-induced elongation led to significant increases in collagen IV and fibronectin protein production, and collagen IV, laminin, and TGF-β1 gene expression, but no significant changes in the MMP or TIMP genes. TNF treatment significantly increased collagen IV gene and protein production. These results suggest that the increase in ECM synthesis in micropattern-elongated ECs is likely regulated with TGF-β1, and this increase in ECM could be relevant to the atheroprotection needed for maintenance of a healthy endothelium in vivo.     

Macrophage-secreted factors promote a profibrotic phenotype in human preadipocytes

White adipose tissue (WAT) in obese humans is characterized by macrophage accumulation the effects of which on WAT biology are not fully understood. We previously demonstrated that macrophage-secreted factors impair preadipocyte differentiation and induce inflammation, and we described the excessive fibrotic deposition in WAT from obese individuals. Microarray analysis revealed significant overexpression of extracellular matrix (ECM) genes in inflammatory preadipocytes. We show here an organized deposition of fibronectin, collagen I, and tenascin-C and clustering of the ECM receptor alpha5 integrin, characterizing inflammatory preadipocytes. Anti-alpha5 integrin-neutralizing antibody decreased proliferation of these cells, underlining the importance of the fibronectin/integrin partnership. Fibronectin-cultured preadipocytes exhibited increased proliferation and expression of both nuclear factor-kappaB and cyclin D1. Small interfering RNA deletion of nuclear factor-kappaB and cyclin D1 showed that these factors link preadipocyte proliferation with inflammation and ECM remodeling. Macrophage-secreted molecules increased preadipocyte migration through an increase in active/phosphorylated focal adhesion kinase. Gene expression and neutralizing antibody experiments suggest that inhibin beta A, a TGF-beta family member, is a major fibrotic factor. Interactions between preadipocytes and macrophages were favored in a three-dimensional collagen I matrix mimicking the fibrotic context of WAT. Cell-rich regions were immunostained for preadipocytes, proliferation, and macrophages in the vicinity of fibrotic WAT from obese individuals. In conclusion, an inflammatory environment leads to profound modifications of the human preadipocyte phenotype, producing fibrotic components with increased migration and proliferation. This phenomenon might play a role in facilitating the constitution of quiescent preadipocyte pools and eventually in the maintenance and aggravation of increased fat mass in obesity.     

Role of extracellular matrix and its regulators in human airway smooth muscle biology

Altered extracellular matrix (ECM) deposition contributing to airway wall remodeling is an important feature of asthma and chronic obstructive pulmonary disease (COPD). The molecular mechanisms of this process are poorly understood. One of the key pathological features of these diseases is thickening of airway walls. This thickening is largely to the result of airway smooth muscle (ASM) cell hyperplasia and hypertrophy as well as increased deposition of ECM proteins such as collagens, elastin, laminin, and proteoglycans around the smooth muscle. Many growth factors and cytokines, including fibroblast growth factor (FGF)-1, FGF-2, and transforming growth factor (TGF)-α₁, that are released from the airway wall have the potential to contribute to airway remodeling, revealed by enhanced ASM proliferation and increased ECM protein deposition. TGF-α₁ and FGF-1 stimulate mRNA expression of collagen I and III in ASM cells, suggesting their role in the deposition of extracellular matrix proteins by ASM cells in the airways of patients with chronic lung diseases. Focus is now on the bidirectional relationship between ASM cells and the ECM. In addition to increased synthesis of ECM proteins, ASM cells can be involved in downregulation of matrix metalloproteinases (MMPs) and upregulation of tissue inhibitors of metalloproteinases (TIMPs), thus eventually contributing to the alteration in ECM. In turn, ECM proteins promote the survival, proliferation, cytokine synthesis, migration, and contraction of human airway smooth muscle cells. Thus, the intertwined relationship of ASM and ECM and their response to stimuli such as chronic inflammation in diseases such as asthma and COPD contribute to the remodeling seen in airways of patients with these diseases.     

Tumstatin regulates the angiogenic and inflammatory potential of airway smooth muscle extracellular matrix

The extracellular matrix (ECM) creates the microenvironment of the tissue; an altered ECM in the asthmatic airway may be central in airway inflammation and remodelling. Tumstatin is a collagen IV‐derived matrikine reduced in the asthmatic airway wall that reverses airway inflammation and remodelling in small and large animal models of asthma. This study hypothesized that the mechanisms underlying the broad asthma‐resolving effects of tumstatin were due to autocrine remodelling of the ECM. Neutrophils and endothelial cells were seeded on decellularized ECM of non‐asthmatic (NA) or asthmatic (A) airway smooth muscle (ASM) cells previously exposed to tumstatin in the presence or absence of a broad matrix metalloproteinase inhibitor, Marimastat. Gene expression in NA and A ASM induced by tumstatin was assessed using RT‐PCR arrays. The presence of tumstatin during ECM deposition affected neutrophil and endothelial cell properties on both NA and A ASM‐derived matrices and this was only partly due to MMP activity. Gene expression patterns in response to tumstatin in NA and A ASM cells were different. Tumstatin may foster an anti‐inflammatory and anti‐angiogenic microenvironment by modifying ASM‐derived ECM. Further work is required to examine whether restoring tumstatin levels in the asthmatic airway represents a potential novel therapeutic approach.     

Collagen modulates gene activation of plasminogen activator system molecules

Skin extracellular matrix (ECM) molecules regulate a variety of cellular activities, including cell movement, which are central to wound healing and metastasis. Regulated cell movement is modulated by proteases and their associated molecules, including the serine proteases urinary-type plasminogen activator (uPA) and tissue-type plasminogen activator (tPA) and their inhibitors (PAIs). As a result of wounding and loss of basement membrane structure, epidermal keratinocytes can become exposed to collagen. To test the hypothesis that during wounding, exposed collagen, the most abundant ECM molecule in the skin, regulates keratinocyte PA and PAI gene expression, we utilized an in vitro model in which activated keratinocytes were cultured in dishes coated with collagen or other ECM substrates. tPA, uPA, and PAI-1 mRNA and enzymatic activity were detected when activated keratinocytes attached to fibronectin, vitronectin, collagen IV, and RGD peptide. In contrast, adhesion to collagen I and collagen III completely suppressed expression of PAI-1 mRNA and protein and further increased tPA expression and activity. Similarly, keratinocyte adhesion to laminin-1 suppressed PAI-1 mRNA and protein expression and increased tPA activity. The suppressive effect of collagen I on PAI-1 gene induction was dependent on the maintenance of its native fibrillar structure. Thus, it would appear that collagen- and laminin-regulated gene expression of molecules associated with plasminogen activation provides an additional dimension in the regulation of cell movement and matrix remodeling in skin wound healing.     

Angiogenic regulatory influence of extracellular matrix deposited by resting state asthmatic and non-asthmatic airway smooth muscle cells is similar

The extracellular matrix (ECM) is the tissue microenvironment that regulates the characteristics of stromal and systemic cells to control processes such as inflammation and angiogenesis. Despite ongoing anti-inflammatory treatment, low levels of inflammation exist in the airways in asthma, which alters ECM deposition by airway smooth muscle (ASM) cells. The altered ECM causes aberrant behaviour of cells, such as endothelial cells, in the airway tissue. We therefore sought to characterize the composition and angiogenic potential of the ECM deposited by asthmatic and non-asthmatic ASM. After 72 hours under non-stimulated conditions, the ECM deposited by primary human asthmatic ASM cells was equal in total protein, collagen I, III and fibronectin content to that from non-asthmatic ASM cells. Further, the matrices of non-asthmatic and asthmatic ASM cells were equivalent in regulating the growth, activity, attachment and migration of primary human umbilical vein endothelial cells (HUVECs). Under basal conditions, asthmatic and non-asthmatic ASM cells intrinsically deposit an ECM of equivalent composition and angiogenic potential. Previous findings indicate that dysregulation of the airway ECM is driven even by low levels of inflammatory provocation. This study suggests the need for more effective anti-inflammatory therapies in asthma to maintain the airway ECM and regulate ECM-mediated aberrant angiogenesis.     

Hyaluronan deposition and correlation with inflammation in a murine ovalbumin model of asthma

Asthma is a chronic inflammatory disease of the airways characterized by airway remodeling, which includes changes in the extracellular matrix (ECM). However the role of the ECM in mediating these changes is poorly understood. Hyaluronan (HA), a major component of the ECM, has been implicated in asthma as well as in many other biological processes. Our study investigates the processes involved in HA synthesis, deposition, localization and degradation during an acute and chronic murine model of ovalbumin (OVA)-induced allergic pulmonary inflammation. Mice were sensitized, challenged to OVA and sacrificed at various time points during an 8-week challenge protocol. Bronchoalveolar lavage (BAL) fluids, blood, and lung tissue were collected for study. RNA, HA, protein and histopathology were analyzed. Analyses of lung sections and BAL fluids revealed an early deposition and an increase in HA levels within 24 h of antigen exposure. HA levels peaked at day 8 in BAL, while inflammatory cell recovery peaked at day 6. Hyaluronan synthase (HAS)1 and HAS2 on RNA levels peaked within 2 h of antigen exposure, while hyaluronidase (HYAL)1 and HYAL2 on RNA levels decreased. Both inflammatory cell infiltrates and collagen deposition co-localized with HA deposition within the lungs. These data support a role for HA in the pathogenesis of inflammation and airway remodeling in a murine model of asthma. HA deposition appears largely due to up regulation of HAS1 and HAS2. In addition, HA appears to provide the scaffolding for inflammatory cell accumulation as well as for new collagen synthesis and deposition.     

Opposite effect of corticosteroids and long-acting beta(2)-agonists on serum- and TGF-beta(1)-induced extracellular matrix deposition by primary human lung fibroblasts

Asthma and chronic obstructive pulmonary disease (COPD) are characterized by chronic airway inflammation and major structural lung tissue changes including increased extracellular matrix (ECM) deposition. Inhaled corticosteroids and long-acting beta(2)-agonists (LABA) are the basic treatment for both diseases, but their effect on airway remodeling remains unclear. In this study, we investigated the effect of corticosteroids and LABA, alone or in combination, on total ECM and collagen deposition, gene expression, cell proliferation, and IL-6, IL-8, and TGF-beta(1) levels by primary human lung fibroblasts. In our model, fibroblasts in 0.3% albumin represented a non-inflammatory condition and stimulation with 5% FCS and/or TGF-beta(1) mimicked an inflammatory environment with activation of tissue repair. FCS (5%) increased total ECM, collagen deposition, cell proliferation, and IL-6, IL-8, and TGF-beta(1) levels. In 0.3% albumin, corticosteroids reduced total ECM and collagen deposition, involving the glucocorticoid receptor (GR) and downregulation of collagen, heat shock protein 47 (Hsp47), and Fli1 mRNA expression. In 5% FCS, corticosteroids increased ECM deposition, involving upregulation of COL4A1 and CTGF mRNA expression. LABA reduced total ECM and collagen deposition under all conditions partly via the beta(2)-adrenergic receptor. In combination, the drugs had an additive effect in the presence or absence of TGF-beta(1) further decreasing ECM deposition in 0.3% albumin whereas counteracting each other in 5% FCS. These data suggest that the effect of corticosteroids, but not of LABA, on ECM deposition by fibroblasts is altered by serum. These findings imply that as soon as airway inflammation is resolved, long-term treatment with combined drugs may beneficially reduce pathological tissue remodeling.     

Augmentation of RANTES-induced extracellular signal-regulated kinase mediated signaling and T cell adhesion by elastase-treated fibronectin

T cells migrating across extracellular matrix (ECM) barriers toward their target, the inflammatory site, should respond to chemoattractant cytokines and to the degradation of ECM by specific enzymes. In this study, we examined the effects of RANTES and ECM proteins treated with human leukocyte elastase on T cell activation and adhesion to the ECM. We found that human peripheral blood T cells briefly suspended with RANTES (0.1-100 ng/ml) had increased phosphorylation of their intracellular extracellular signal-regulated kinase (ERK), a mitogen-activated protein kinase involved in the activation of several intracellular downstream effector molecules implicated in cell adhesion and migration. Consequently, a small portion (12-20%) of the responding cells adhered to fibronectin (FN). However, when the T cells were exposed to RANTES in the presence of native immobilized FN, laminin, or collagen type I, ERK phosphorylation was partially inhibited, suggesting that this form of the ECM proteins can down-regulate RANTES-induced intracellular signaling. In contrast, when the T cells were exposed to RANTES in the presence of elastase-treated immobilized FN, but not to elastase-treated laminin, ERK phosphorylation was markedly increased. Furthermore, a large percentage (30%) of RANTES-activated T cells adhered to the enzymatically treated FN in a beta1 integrin-dependent fashion. Thus, while migrating along chemotactic gradients within the ECM, T cells can adapt their adhesive performance according to the level of cleavage induced by enzymes to the matrix.     

Streptococcus suis serotype 2 binding to extracellular matrix proteins

Streptococcus suis serotype 2 is a major swine and human pathogen that causes septicemia and meningitis. The ability of S. suis serotype 2 to bind to different extracellular matrix (ECM) proteins was evaluated by ELISA. All 23 strains tested bound to plasma and cellular fibronectin and collagen types I, III, and V, some to fibrin, vitronectin, and laminin, and none to the other ECM proteins tested. An unencapsulated isogenic mutant bound to ECM proteins better than its parental encapsulated strain, suggesting that the polysaccharide capsule interfered with binding. Cross-inhibition was observed between soluble plasma fibronectin and collagens in the ECM adherence assay, indicating that binding domains for both proteins exist on the same or nearby bacterial surface molecules. On the other hand, pre-incubation with plasma fibronectin increased binding to collagen IV, suggesting that S. suis might use fibronectin as a bridging molecule. The results of heat treatment and proteolytic digestion suggest that adhesins for these ECM proteins are proteinaceous in nature.     

Ultraviolet B and A irradiation induces fibromodulin expression in human fibroblasts in vitro

Ultraviolet (UV) radiation affects the extracellular matrix (ECM) of the human skin. The small leucine-rich repeat protein fibromodulin interacts with type I and II collagen fibrils, thereby affecting ECM assembly. The aim of this study was to evaluate whether short wave UV (UVB) or long wave UV (UVA) irradiation influences fibromodulin expression. Exponentially growing human fibroblasts (IMR-90 cells) were exposed to increasing doses of UVB (2.5–60 mJ/cm²) or UVA (0.5–10 J/cm²). After UV irradiation fibromodulin, p21 and GADD45 levels were evaluated as well as cell viability, reactive oxygen species formation (ROS) and DNA damage. We found that fibromodulin expression: (i) increased after UVB and UVA irradiation; (ii) was 10-fold higher after UVA (10 J/cm²) versus 5-fold with UVB (10 mJ/cm²); (iii) correlated with reactive oxygen species formation, particularly after UVA; and (iv) was linked to the DNA damage binding protein (DDB1) translocation in the nucleus, particularly after UVB. These results further suggest that the UV-induced fibromodulin increase could counteract the UV-induced connective tissue damage, promoting the assembly of new collagen fibrils.     

Decreased caveolin‐1 levels contribute to fibrosis and deposition of extracellular IGFBP‐5

Our previous studies have demonstrated increased expression of insulin‐like growth factor binding protein‐5 (IGFBP‐5) in fibrotic tissues and IGFBP‐5 induction of extracellular matrix (ECM) components. The mechanism resulting in increased IGFBP‐5 in the extracellular milieu of fibrotic fibroblasts is unknown. Since Caveolin‐1 (Cav‐1) has been implicated to play a role in membrane trafficking and signal transduction in tissue fibrosis, we examined the effect of Cav‐1 on IGFBP‐5 internalization, trafficking and secretion. We demonstrated that IGFBP‐5 localized to lipid rafts in human lung fibroblasts and bound Cav‐1. Cav‐1 was detected in the nucleus in IGFBP‐5‐expressing fibroblasts, within aggregates enriched with IGFBP‐5, suggesting a coordinate trafficking of IGFBP‐5 and Cav‐1 from the plasma membrane to the nucleus. This trafficking was dependent on Cav‐1 as fibroblasts from Cav‐1 null mice had increased extracellular IGFBP‐5, and as fibroblasts in which Cav‐1 was silenced or lipid raft structure was disrupted through cholesterol depletion also had defective IGFBP‐5 internalization. Restoration of Cav‐1 function through administration of Cav‐1 scaffolding peptide dramatically increased IGFBP‐5 uptake. Finally, we demonstrated that IGFBP‐5 in the ECM protects fibronectin from proteolytic degradation. Taken together, our findings identify a novel role for Cav‐1 in the internalization and nuclear trafficking of IGFBP‐5. Decreased Cav‐1 expression in fibrotic diseases likely leads to increased deposition of IGFBP‐5 in the ECM with subsequent reduction in ECM degradation, thus identifying a mechanism by which reduced Cav‐1 and increased IGFBP‐5 concomitantly contribute to the perpetuation of fibrosis.     

Recovery of extracellular matrix components by enalapril maleate during the repair process of ultraviolet B-induced wrinkles in mouse skin

The renin–angiotensin system is known to be involved in skin remodeling and inflammation. Previously, we reported that ultraviolet B (UVB) irradiation enhanced angiotensin-converting enzyme (ACE) expression and angiotensin II levels in hairless mouse skin, and an ACE inhibitor, enalapril maleate (EM), accelerated repair of UVB-induced wrinkles. In this study, we analyzed gene expression profiles by DNA microarray and protein distribution patterns using an immunofluorescence method to clarify the process of EM-accelerated wrinkle repair in UVB-irradiated hairless mouse skin. In the microarray analysis, we detected EM-induced up-regulation of various extracellular matrix (ECM)-related genes in the UVB-irradiated skin. In the immunofluorescence, we confirmed that type I collagen α1 chain, fibrillin 1, elastin and dystroglycan 1 in the skin decreased after repeated UVB irradiation but staining for these proteins was improved by EM treatment. In addition, ADAMTS2 and MMP-14 also increased in the EM-treated skin. Although the relationship between these molecules and wrinkle formation is not clear yet, our present data suggest that the molecules are involved in the repair of UVB-induced wrinkles.