Abstract
Multicellular organisms synthesize and renew components of their subcellular and scaffolding proteins, collectively known as the extracellular matrix molecules (ECMs). In the lung, ECMs maintain tensile strength, elasticity, and dictate the specialized function of multiple cell lineages. These functions are critical in lung homeostatic processes including cellular migration and proliferation during morphogenesis or in response to repair. Alterations in lung ECMs that expose cells to new cryptic fragments, generated in response to endogenous proteinases or exogenous toxins, are associated with the development of several common respiratory diseases. How lung ECMs provide or relay vital signals to epithelial and mesenchymal cells has shed new light on development and progression of several common chronic respiratory diseases. This review will consider how ECMs regulate lung homeostasis and their reorganization under pathological conditions that can modulate the inflammatory diseases asthma, chronic obstructive pulmonary disease (COPD), and idiopathic pulmonary fibrosis (IPF). Better understanding of changes in the distribution of lung ECM could provide novel therapeutic approaches to treat chronic lung diseases.
Introduction
Genomic and proteomic studies have identified over 300 different extracellular matrix molecules (hereafter referred to as ECM) that control the structure and function of multicellular organisms [1]. Although they were first recognized for their function as scaffolding and structural molecules that support of all living cells, the ECM are now known as critical, acellular components of cells because they orchestrate essential cellular processes, including morphogenesis, signal transduction, migration, proliferation and wound repair [2–4]. While some components of the ECM are highly preserved among different tissues, their unique qualities provide a window into organ-specific functions. For instance, the rigidity and pliability of the ECM is dependent on their macromolecular components, which are dictated by tissue-specific functions.
Predominately, proteins and glycoproteins comprise the largest portion of the ECM molecular niches [5, 6]. Two primary forms of matrices exist: 1) the basement membrane ECM that lie immediately below epithelial and endothelial cells, and 2) the acellular, interstitial ECM components embedded within the tissue that surrounds cells. Non-fibrillar collagens, laminins, glycoproteins, and proteoglycans make up most of the basement membrane, which compartmentalize the epithelium or endothelium from their surrounding stroma [7, 8]. The primary role of basement membrane ECM includes barrier function that is especially important for the mucosal tissues (e.g., respiratory, gastrointestinal, and genitourinary organs) [7, 8]. The tissue-specific acellular interstitial matrix is composed of connective tissue with large concentrations of fibrous proteins (e.g., collagen, elastin), fibronectin and proteoglycans that are assembled into intricate fibril networks [9–11]. The interstitial matrix provides the necessary scaffolding to enable structural stability and resistance among all tissue [9–11].
In addition to their major roles in maintaining structural stability and tissue homeostasis, ECM can also modulate cell signaling as intact or modified molecules. For example, ECMs can activate or repress cell-specific transcription factors, supporting their direct role in tissue morphogenesis and cell fate [12, 13], while secreted proteinases can cleave and modify ECMs, further diversifying their function [14]. The term ‘matrikine’ or ‘matricryptin’ has been attributed to the bioactive fragments of extracellular matrix that modulate multiple physiological processes [14–16]. A number of ECM-derived matrikines have been shown to be involved in inflammation and immune homeostasis, while others are implicated in tumor metabolism and invasion [14–16]. Here, we discuss several unique features of the lung ECM as they relate to disease pathogenesis driven by immune modulation and matrikine signaling functions. This review focuses on the role of ECM in the pathogenesis of idiopathic pulmonary fibrosis, asthma, and chronic obstructive pulmonary disease.
Lung ECM
The lungs provide two vital physiological functions: passive gas exchange (alveolar respiration), and lung-specific innate immune defense against pathogenic insults that protect the airway epithelial barrier. Notably, the lung’s elastin-rich ECM is molecularly distinct from that of the kidney, which is a more rigid organ and is predominantly composed of several types of collagens (Type I, III, VI, VII,) that are less abundant in the lung [17]. Furthermore, although the intestine and lung share a common embryonic origin, the gut ECM has higher concentrations of laminins that are critical for tight cell-to-cell junctions that are necessary for interactions with the gut microbiota [18]. Lung ECM is often altered in response to different environmental insults that damage airway epithelia, such as chronic exposure to inhaled antigens, cigarette smoke, air pollution, viral or bacterial pathogens, and trauma [19]. Injured epithelial cells can promote specific ECM remodeling that in turn affects their local cellular function. Therefore, the unique composition of lung ECMs that support bronchial epithelial cells in the proximal conducting airway secrete more collagens, laminins, and proteoglycans [20], whereas, in the alveolar termini, type I epithelial cell walls nearly fuse with those of proximal capillary endothelial cells, creating an ultrathin elastin-predominant ECM to permit efficient gas exchange [20, 21] (Figure 1).
A further unique aspect of the lung is the notable differences in the ECM basement membrane components and lung interstitial parenchyma. The airway basement membrane contains proteins (collagen IV & V, numerous proteoglycans, enactin, and laminins), which are specialized to promote airflow in the proximal airway and enhance appropriate gas exchange at the terminal alveoli [21].
Whilst specialized mesenchymal cells (e.g., myofibroblasts, fibrocytes, smooth muscle cells) within the lung interstitial space can secrete distinct sets of ECM molecules (e.g., collagens, laminin, elastin, proteoglycans, hyaluronans, etc.) [20, 22], they can also produce bioactive matrikines contributing to lung disease pathogenesis (Figure 2). For example, degradation of laminin by several MMPs (e.g. MMP3, MMP12, MMP14, MMP20) or neutrophil elastase, generates, laminin-332 and laminin-5, two matrikines that bind to EGFR to regulate epithelial proliferation (Figure 3) [23, 24]. In a preclinical model of asthma, overexpression of hyaluronan synthase 2 (HAS2) in myofibroblasts and smooth muscle cells resulted in increased airway fibrosis and reduced AHR. These findings suggest that HA accumulation in the airway wall may contribute to airway thickening in asthma via HAS2 [25].
Although several scaffolding molecules in the lung are required for normal ECM assembly [26], their major components are collagens, and elastin molecules that constitute over approximately 60% [27], and 24% [28, 29] of dry lung weight, respectively. As such, dysregulation of collagen and elastin in the ECMs contribute to multiple pathological lung conditions. In this review, we highlight the primary components of lung ECM and describe how these proteins and their fragments are harnessed to promote health, and in instances of injury, encourage disease.
1. Collagen
Multiple isoforms of collagen provide structural stability and tensile strength in the lung [30]. Approximately 28 different types of collagen have been identified, all containing repetitive Glycine-Proline-X amino acid sequences that enable then to form triple helices that contribute to the intermolecular bonding and strength of collagen fibers [7, 30, 31]. Fibrillar collagens, or collagens that are post-translationally modified by enzymes such as lysyl oxidase, form polymerized fibers, and are the most abundant lung isoforms [21, 32, 33]. The triple helical structure of collagens I and III form a tight fibrous network throughout the large conducting airways, bronchi, and bronchioles, providing the strength and stability required for their proper function [32, 34, 35].
Non-fibrillar collagens, (e.g., collagen IV and V), that are found in the lung basement membrane, contain interruptions or non-Glycine-Proline-X sequences in their triple helical domains that result in kinks in the macromolecular structure that facilitate interactions with other ECM components [36, 37]. Collagens in the lung basement membrane and interstitial space are vital molecular scaffolds for necessary physiological processes such as fibroblast proliferation, migration, and adhesion. For instance, transmembrane cell adhesion molecules such as the integrin subunits α1, α2, α10, α11, recognize and bind to collagen (type I), facilitating cellular locomotion and cell migration during development [38–40]. Frequent lung collagen turnover of different isoforms during acute inflammation [41] further supports their functional role in essential biological processes, including cellular proliferation and migration. Collagens are implicated in the pathogenesis of lung diseases characterized by both matrix deposition and degradation. Here, we describe the roles of collagen and its associated fragments in the pathogenesis of idiopathic pulmonary fibrosis, COPD, and asthma.
1.1 Collagen in IPF Pathogenesis
Collagen deposition is a prominent feature of the fibrotic or scar-like lesions found in the lungs of patients with pulmonary fibrosis [42]. Accumulation of excessive fibrous tissue in the lungs physically impedes, and functionally restricts adequate gas exchange [43, 44]. Idiopathic Pulmonary Fibrosis (IPF), a prototypic and incurable form of fibrotic lung diseases, is characterized by increased numbers of myofibroblasts that aberrantly produce collagen I, that in turn expand fibrotic foci in the lungs [45]. The molecular mechanisms by which myofibroblast drive IPF are currently an area of active investigation; however, reduced expression of PTEN has been linked to the repression of FOXO3a, a transcriptional activator of collagen I, which is also a known apoptosis-inducing protein [46–48]. However, whether these mechanisms also control collagen expression in IPF remains unclear. Decellularization of IPF lungs has demonstrated abnormal expression of several collagens, particularly fibrillar collagen III [49]. Other groups have corroborated the role of collagens in the progressive lung remodeling associated with IPF whereby fibrillar collagen III is associated with early disease onset, but collagen I is associated with advanced disease [50].
Cytokines are thought to drive the progression of IPF by increasing deposition of collagens [51]. Specifically, TGF-β expression is upregulated in fibrotic lungs and has been shown to induce the differentiation of myofibroblasts, which orchestrate disease progression [52–54], enhance collagen gene transcription [55, 56], and alter the balance between matrix metalloproteinase and their associated tissue inhibitors of metalloproteinases (TIMPs) to favor accumulation of matrix components [57, 58].
1.2. Collagen in COPD Pathogenesis
In response to cigarette smoke, innate and adaptive immune cells are recruited to the lungs and promote development of chronic obstructive pulmonary disease (COPD) [59, 60]. Collagen turnover is highly associated with COPD pathogenesis, which is in part mediated by activation and recruitment of innate immune cells (e.g., macrophages and neutrophils) to the lungs. Specifically, the lungs of smokers typically show increased concentrations of MMP2, MMP8, MMP9 and prolyl endopeptidases that can cleave collagen to form the matrikines Proline-Glycine-Proline (PGP) and acetylated-PGP (Ac-PGP) [61, 62]. These collagen-derived matrikines have chemotactic properties that can perpetuate lung inflammation because they utilize the chemokine receptors CXCR1 and CXCR2, to recruit neutrophils to the lungs [61, 62]. However, collagen-derived PGPs are degraded by the aminopeptidase activity of leukotriene A4 hydroxylase, which limits their pro-inflammatory function [63, 64]. Clinically PGP and N-a-PGP concentrations are elevated in the sputum and serum of smokers with COPD when compared to asthmatic and/or healthy controls; furthermore, fluctuations in PGP concentration correlate in disease exacerbations [65, 66]. The pathogenic roles for PGP and Ac-PGP in COPD are also corroborated by experimental animal models, which demonstrate that PGP enhances lung tissue destruction and emphysema (Figure 2) [67].
Small airways that are less than 2 mm in diameter show minimal airflow resistance under normal conditions but are highly abnormal in smokers with COPD. A comprehensive quantitative histology, computed tomography, and gene expression analysis of smokers with different levels of COPD severity showed that bronchiolar tissue is reduced in COPD, but while total tissue collagen is reduced, there was a relative increase in collagen-3 over collagen-1 [68]. The authors concluded that narrowing of the terminal bronchioles occurs early in COPD, involving small airway remodeling and abnormal collagen deposition [68]. Finally, in smokers, development of upper lobe emphysema and lower lobe fibrosis, or combined pulmonary fibrosis and emphysema (CPFE), is a defined endotype that portends a poor prognosis [69, 70]. Little is known about the pathophysiological responses to cigarette smoke that can promote emphysema and fibrosis, but in one study that compared smokers with IPF, emphysema, or CPFE, serum SP-A and SP-D levels were higher in patients with fibrosis irrespective of emphysema and which also correlated with disease severity [71].
1.3 Collagen in Asthma
The allergic airway disease asthma is defined by the presence of intermittent airway obstruction, termed hyper-responsiveness (AHR), that narrows bronchi and clinically manifests as wheezing and dyspnea. Exposure to allergens triggers recruitment of different innate inflammatory cells, including mast cells, eosinophils and neutrophils that release pre-formed vesicles that contain ECM remodeling collagenases (e.g., MMP2 and MMP9) in the lungs [72, 73]. Consequently, targeting collagenases to reduce collagen turnover and reduce lung inflammation has been considered a potential asthma treatment [74]. Notably however, using preclinical models of asthma, deficiency in MMP2, MMP9, or molecular inhibition of MMPs not only did not alleviate allergic lung inflammation, but resulted in reduced airway chemotactic gradient formation, culminating in exacerbated lung inflammation and asphyxiation [75–77]. These studies point to the diverse and non-redundant roles for collagenases that are acutely elevated in T helper type 2 (Th2) mediated lung inflammation.
Chronic allergic airway inflammation can also promote subepithelial fibrosis characterized by excessive deposition and/or reorganization of type I, III, and IV collagens [78–82]. Several associated proteins including fibronectin, periostin [83, 84], Fibulin-1 (Fbln1) [85] also play key roles in lung ECM formation and contribute to mucus hypersecretion and Th2-associated inflammation [86]. In preclinical models of asthma, inhibition or genetic ablation of Fbln1c, a Fbln1 isomer, reduced airway collagen deposition, mucin production, and protected against AHR. Fbln1c deficiency also attenuated responses to allergens, reduced interstitial contractile cells, and lowered Th2 inflammatory cytokines. These findings suggest that therapeutic targeting of proteins that destabilize collagen in asthma could reduce subepithelial fibrosis and inflammation [86].
Airway smooth muscle cells secrete collagen in response to Th2 inflammatory cytokines and can contribute to airway wall thickening in severe asthma [25]. Transgenic overexpression of IL-13, a canonical Th2 cytokine, in mouse lungs can induce allergic inflammation, characterized by mucus hypersecretion and subepithelial fibrosis [87]. Expression of IL-5 and IL-13 by conventional T cells or innate lymphoid type 2 cells (ILC2s) is also important in orchestrating chronic structural changes in the lungs. Furthermore, impeding IL-13-mediated signaling by neutralizing antibodies or decoy receptors can reduce airway remodeling and fibrosis associated with asthma [88–90]. Although much remains to be elucidated concerning the mechanisms by which IL-13 induces subepithelial fibrosis in asthma, studies using in vitro systems have demonstrated that IL-13-associated signaling modulates fibroblasts and myofibroblasts to enhance TGF-β-induced procollagen production and decrease collagenase (MMP1 and MMP3) activity via increases in TIMP expression (Figure 3) [89, 91, 92].
2. Elastin
Elastin fibers, arguably the most critical component of lung ECM, control respiratory compliance because of their ability to stretch up to 140%, in contrast to collagen, which provides tensile force, but can only stretch by 2% [93]. Lung elastin fibers are composed of approximately 90% tropoelastin and 10% microfibril proteins (e.g., fibulin, latent TGF-β binding proteins (LTBPs), fibrillin and microfibrin-associated glycoprotein (MAGP)) [29, 94]. After assembly, elastin fibers are highly insoluble because lysyl oxidase crosslinks tropoelastin, its soluble precursor, which contains multiple highly repetitive hydrophilic lysine rich domains as well as hydrophobic amino acids (e.g., valine, proline, alanine, and glycine) that confer elastin’s elasticity [95].
The unique structural features of elastin fibers provide it with stability and resistance against proteolytic degradation. Deposition of elastin fibers in the lung begin during the pseudoglandular, but is accelerated in the alveolarization stages of development. Maturation of lung elastin fibers requires cross-linking enzymes that assemble tropoelastin with microfibril proteins. Thus, it is not surprising that in response to injury, newly formed elastin fibrils are often less organized, and have reduced elasticity [96]. Under non-pathological conditions, the rate of elastin degradation in the lung, as estimated by radioimmunoassay with 14C labeling and desmosine quantitation showed a nearly 70-year half-life, further supporting the unique molecular stability of elastin. This finding contrasts notably with the approximate 10% per day turnover of lung collagen [97–100]. These biological insights into elastin longevity highlight the importance of this macromolecule in its structure, integrity, and proper function in the lungs.
Degradation of lung elastin requires activation of specific MMPs as well as the aspartic, cysteine, and serine families of proteinases. Under pathological conditions, elastases are released from mesenchymal cells (fibroblasts, myofibroblasts, etc.) and/or innate immune cells (e.g., neutrophils, eosinophils, mast cells, and macrophages) that cleave elastin, thereby exposing new antigenic sites that can be recognized by T and B cells. Elastin fragments have been found in the serum of smokers with COPD [101] and have been shown to induce auto-reactive immune responses [102, 103], (discussed below under Elastin in COPD). Elastin degradation also generates bioactive matrikines, called elastokines, such as the Val-Gly-Val-Ala-Pro-Gly (VGVAPG) hexamer that influences cell migration, mitogenesis, and other cellular signaling [104, 105]. Similarly, the elastokine consensus sequence GXXPG forms type VIII β-turn structures that maintain its stable binding with the elastin receptor (S-Gal complex) [106].
2.1 Elastin in IPF pathogenesis
In response to lung injury, mesenchymal cells increase the expression of tropoelastin mRNA; however, newly synthesized elastin remains highly disorganized, i.e., amorphous [94]. Following injury, TGF-β, the prototypic pro-fibrotic cytokine, promotes transcriptional expression and stability of the elastin mRNA mediated by activation of the phosphatidylinositol 3-kinase (PI3K)/Akt pathway [107–112]. Increased elastin expression has been shown to promote lung fibrosis in part by increasing collagen deposition. For example, in a bleomycin-model of lung fibrosis, elastin expression positively correlated with deposition of newly synthesized collagen [113]. Furthermore, in response to TGF-β, elastin but not collagen can increase differentiation of fibroblasts to myofibroblasts, indicating a pathogenic role for elastin in IPF [114]. Lung elastin is further stabilized by the epithelial integrin αvβ6 that bind to the latency-associated peptide (LAP), facilitating activation of TGF-β, suppression of MMP12, and increases in TIMP-1 expression in macrophages [114–116]. Furthermore, decellularized lung ECM from IPF patients, but not controls, can induce a specific set of genes in fibroblasts that are targets of microRNA(miR)-29, indicating that abnormal ECM can program new cellular responses [117]. Whether amorphous elastin or TGF-β play direct roles in these aberrant signaling remains an area of active investigation.
2.2. Elastin in Emphysema pathogenesis
Targeted disruption of proteins required for elastin fiber assembly (fibulin, latent transforming growth factor-β-binding protein-4 (Ltbp4), and lysyl oxidase (Lox)) as well as genetic deficiencies of the elastin gene (Eln+/−) result in abnormal lung development [118–121] and increased susceptibility to smoke-induced emphysema [110]. Genome-wide gene expression profiling using lung tissue samples from current and former smokers showed upregulation of fibulin-5 (FBLN5), elastin (ELN), and LTBP2 [122], indicating a dynamic process that is activated to repair lung elastin fibers in response to chronic smoke exposure. Furthermore, spatio-temporal expression of FBLN5, ELN, LTBP2 and microfibril associated protein 4 in response to cigarette smoke further provides strong support for their critical roles in lung elastin fiber repair in response to chronic inflammation in emphysema [122].
Three of the most important elastolytic enzymes: MMP9, MMP12, and neutrophil elastase, are produced by innate immune cells [77]. In response to elastolysis, newly formed elastin fragments or elastokines, recruit monocytes to the lungs, whereby they can differentiate into macrophages and further release MMP12 that inactivates alpha 1 anti-trypsin, deficiency of which is associated with early onset emphysema [123]. Elastokines also induce expression of NADPH oxidase (NOX2) in macrophages. This enzyme in turn can inhibit SIRT1, negative regulator of MMP9 expression in neutrophils and macrophages [124]. Neutrophil elastase can increase the availability of epidermal growth factor (EGF) for lung fibroblasts, which consequently stabilizes the Smad transcriptional corepressor, TG-interacting factor (TGIF), inhibit TGF-β production, and reduce new tropoelastin synthesis [125–127]. These findings suggest that elastolytic enzymes may have dual functions: 1) direct cleavage of elastin fibers, and 2) reduction in new elastin fiber biogenesis that together aggravate the lung repair process in response to cigarette smoke exposure.
Detection of desmosine, a biomarker of emphysema, signifies active breakdown of elastin in active and former smokers [128]. Several lines of evidence strongly support a role for the induction of acquired immunity to degraded elastin fragments in a subset of smokers who develop emphysema [129]. Specifically, T and B lymphocytes that recognize and respond to elastin fragments in the context of major histocompatibility complex class II (MHC II), are associated with emphysema severity [103]. Furthermore, elastin-specific T cells have been cloned from the peripheral blood of active and former smokers [102], and former smokers have been shown to harbor interferon gamma (IFN-γ) expressing T helper type 1 (Th1) and Th17 cells in their lungs [130]. The clinical significance of anti-elastin immunity is underscored by the positive correlation between the loss of lung function and Th1-specific immune responses to lung elastin fragments [131]. The mechanism for development of elastin-specific acquired immunity is due in part to cigarette smoke-induced activation of lung myeloid dendritic cells (mDC) [130]. Identification of specific regions within the elastin molecule that promote autoimmune responses could provide novel T cell-based therapies in COPD and emphysema.
Final considerations and new advances
Recent advances targeting ECM production and repair have provided novel approaches that could be used to treat chronic lung diseases. For example, doxycycline (DOX), a broad-spectrum MMP inhibitor, has been used to inhibit elastin breakdown and allow regeneration and repair of elastin in models of aortic aneurysm [132, 133]. DOX has also been shown to inhibit c-Jun-N-terminal kinase 2 (JNK 2), which promotes TGF-β1 expression and elastogenesis mediated by the lysyl oxidase crosslinking of elastin [134]. Because systemic MMP inhibition can prevent normal ECM turnover in healthy tissues [135–137], efforts are now being directed towards local delivery of MMP inhibitors. For instance, applied magnetic fields have been used to deliver DOX via incorporation of super-paramagnetic iron oxide polymer nanoparticles (SPIONs) to localize elastin restoration in the aortic wall [133]. Similarly, SPIONs could be applied to emphysematous lung to inhibit MMPs, an intervention that could lead to regeneration of normal lung.
Another novel bioengineering approach is the utilization of photo cross-linkable, elastin-like polypeptide (ELP) hydrogels. These matrices have highly extensible properties and have been used to generate scaffolds to seal rents in the lung parenchyma [138, 139]. A futuristic approach to generate functional alveoli could include seeding these synthetic, elastin scaffold structures with mesenchymal stem cells (MSCs), induced pluripotent stem cells (iPSCs), or the newly identified alveolar epithelial stem cells expressing Lgr5 [140] to generate new lung tissue. Finally, mesenchymal alveolar niche cells (MANCs), a functionally unique lung mesenchymal population, have been shown to secrete necessary molecular cues, (e.g., IL-6 and Fgf7), to form ECM and promote proliferation and regeneration of the alveolar epithelium [141]. Together, these novel, synthetic biotechnologies and lung stem cell discoveries provide exciting advances in medicine that could lead to restoring lung tissue structure and function in instances of chronic lung disease.
Highlights.
The extracellular matrix plays key roles in lung structural integrity, and function.
Proteinases generate cryptic extracellular matrix fragments or ‘matrikines’ that further diversify their function.
Fragments of collagen and elastin play pathogenic roles in several common chronic inflammatory lung diseases including asthma, idiopathic pulmonary fibrosis, and emphysema.
Novel bioengineering approaches utilize photo-crosslinkable elastin-like polypeptides (ELPs) hydrogel to repair or seal injured lung.
Acknowledgments
Funding: This work was supported by the R01HL117181-01, (FK, DBC), CX000104 (FK) VA Merit Award, DAMD W81XWH-16-1-0361 (FK).
Footnotes
Competing interests: The authors do not have any conflict of interest
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