Hostname: page-component-cd9895bd7-lnqnp Total loading time: 0 Render date: 2024-12-26T15:01:57.041Z Has data issue: false hasContentIssue false

The emerging role of NOTCH3 receptor signalling in human lung diseases

Published online by Cambridge University Press:  02 September 2022

Manish Bodas
Affiliation:
Department of Medicine, Section of Pulmonary, Critical Care & Sleep Medicine, University of Oklahoma Health Sciences Center, Oklahoma City, OK 73104, USA
Bharathiraja Subramaniyan
Affiliation:
Department of Medicine, Section of Pulmonary, Critical Care & Sleep Medicine, University of Oklahoma Health Sciences Center, Oklahoma City, OK 73104, USA
Harry Karmouty-Quintana
Affiliation:
Department of Biochemistry and Molecular Biology, McGovern Medical School, University of Texas Health Science Center at Houston, Houston, Texas 77030, USA Department of Internal Medicine, Divisions of Critical Care, Pulmonary and Sleep Medicine, McGovern Medical School, University of Texas Health Science Center at Houston, Houston, Texas 77030, USA
Peter F. Vitiello
Affiliation:
Department of Pediatrics, University of Oklahoma Health Sciences Center, Oklahoma City, OK 73104, USA
Matthew S. Walters*
Affiliation:
Department of Medicine, Section of Pulmonary, Critical Care & Sleep Medicine, University of Oklahoma Health Sciences Center, Oklahoma City, OK 73104, USA
*
Author for correspondence: Matthew S. Walters, E-mail: Matthew-S-Walters@ouhsc.edu
Rights & Permissions [Opens in a new window]

Abstract

The mammalian respiratory system or lung is a tree-like branching structure, and the main site of gas exchange with the external environment. Structurally, the lung is broadly classified into the proximal (or conducting) airways and the distal alveolar region, where the gas exchange occurs. In parallel with the respiratory tree, the pulmonary vasculature starts with large pulmonary arteries that subdivide rapidly ending in capillaries adjacent to alveolar structures to enable gas exchange. The NOTCH signalling pathway plays an important role in lung development, differentiation and regeneration post-injury. Signalling via the NOTCH pathway is mediated through activation of four NOTCH receptors (NOTCH1-4), with each receptor capable of regulating unique biological processes. Dysregulation of the NOTCH pathway has been associated with development and pathophysiology of multiple adult acute and chronic lung diseases. This includes accumulating evidence that alteration of NOTCH3 signalling plays an important role in the development and pathogenesis of chronic obstructive pulmonary disease, lung cancer, asthma, idiopathic pulmonary fibrosis and pulmonary arterial hypertension. Herein, we provide a comprehensive summary of the role of NOTCH3 signalling in regulating repair/regeneration of the adult lung, its association with development of lung disease and potential therapeutic strategies to target its signalling activity.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press

Introduction

The mammalian respiratory system or lung is one of the most critical organ systems, and the main site of gas exchange with the external environment (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8). Structurally, the human lung is a tree-like branching structure which is broadly classified into the conducting airways (proximal and distal), which terminate at the respiratory bronchioles and form a connection with the alveolar region, where the gas exchange occurs (Fig. 1a) (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8). Similar to the respiratory tree, the pulmonary circulation subdivides rapidly and branches into capillaries that surround the alveolar compartment, allowing for a large surface area for gas exchange (Ref. Reference Kandathil and Chamarthy9). However, contrary to the airway tree, segments of the pulmonary artery branch off early at irregular but frequent intervals to enter the lung parenchyma. This results in the pulmonary arterial tree having more branches than the bronchial one (Refs Reference Gil10, Reference Elliott and Reid11). Following gas exchange in the capillary beds, oxygenated blood is returned to the heart by pulmonary veins (Ref. Reference Kandathil and Chamarthy9).

Fig. 1. The human respiratory system. (a) Structure of the human respiratory system. (b) Structure of the human pseudostratified mucociliary epithelium. The pseudostratified mucociliary airway epithelium is a continuous single layer of epithelial cells with each cell having direct contact with the basement membrane. The mucociliary epithelium consists of several cell types which can be identified by expression of specific markers. These include, basal cells (KRT5 + , TP63 + ), intermediate (KRT8 + , KRT13 + ), multi-ciliated (FOXJ1 + , DNAI1 + ), goblet secretory (MUC5AC + , MUC5B + ), club secretory (SCGB1A1 + , SCGB3A2 + ), neuroendocrine (CALCA + , ASCL1 + ), pulmonary ionocytes (FOXI1 + , CFTR + ) and brush/tuft (TSLP + , IL-25 + ). The trachea and large airways also harbour submucosal glands which contain additional specialised epithelial cell populations including, serous (LTF + , DCCP1 + ), mucous (MUC5B + , TFF2 + ) and myoepithelial (EPCAM + , ACTA2 + ). Located underneath the basement membrane are a large number of non-epithelial cell populations required to maintain proper structure and function of the respiratory system, including cartilage rings (trachea and large airways only), smooth muscle, fibroblasts, blood vessels, nerves and immune cells (e.g., lymphocytes and dendritic cells). (c) Structure of the human respiratory bronchiole and alveolar epithelium. Terminal respiratory bronchioles are lined predominantly with cuboidal secretory cells (SCGB1A1 + , SCGB3A2 + ) which contain the recently identified progenitor populations termed respiratory airway secretory (RAS) or terminal and respiratory bronchiole secretory cells (TRB-SCs). In contrast, the alveoli consist of alveolar type 1 (AGER + , AQP5 + ) and type 2 (SFTPC + , ABCA3 + ) cells. Type 1 cells are the predominant epithelial cell type in the alveolus and comprise approximately 95% of the gas exchange surface with the underlying vasculature in the lung.

The conducting airway, comprising of the nasal cavity, trachea, bronchi and bronchioles, functions as a conduit of air to and from the alveoli and is the foremost physical barrier and first line of defence against inhaled pathogens (e.g., viruses and bacteria) and particulates (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8). This efficient barrier is formed by the pseudostratified mucociliary airway epithelium, a continuous single layer of epithelial cells, with each cell having a direct contact to the basement membrane (Fig. 1b) (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8). Located underneath the basement membrane are a large number of non-epithelial cell populations required to maintain proper structure and function of the respiratory system, including cartilage rings (trachea and large airways only), smooth muscle, fibroblasts, blood vessels, nerves and immune cells (e.g., lymphocytes and dendritic cells) (Fig. 1b) (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8). The mucociliary epithelium consists of several cell types, such as basal cells (BCs), intermediate, multi-ciliated, secretory (mucus producing ‘goblet’; or non-mucus producing ‘club’ cells), neuroendocrine and many other rare cell types, such as pulmonary ionocytes and brush/tuft (Fig. 1b) (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8, Reference Deprez12). Both multi-ciliated and secretory cells are critical to the barrier function of the mucociliary epithelium, as they form the mucociliary escalator system, which helps cleanse the airways (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8). In this process, the inhaled particulates and pathogens trapped on the apical surface of the epithelium by secretory cell-derived mucins and defence-related molecules are removed from the airways in a retrograde manner by the action of multi-ciliated cells. In addition to the luminal secretory cell populations, the trachea and large airways also harbour submucosal glands which contain additional specialised epithelial cell populations including, serous, mucous and myoepithelial that contribute to the production of luminal mucus (Fig. 1b) (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8). BCs are the resident stem/progenitor cells of the adult mucociliary airway epithelium that are responsible for the normal turnover of airway epithelial cells during homeostasis, and the repair and regeneration of the airway epithelium following injury (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8, Reference Busch, Lorenzana and Ryan13, Reference Rock, Randell and Hogan14, Reference Aros15). In contrast to the conducting airways, the terminal respiratory bronchioles are predominantly lined with cuboidal secretory cells which contain the recently identified progenitor populations termed respiratory airway secretory or terminal and respiratory bronchiole secretory cells (Fig. 1c) (Refs Reference Basil16, Reference Kadur Lakshminarasimha Murthy17). Upon transition to the alveoli, barrier function is mediated by the alveolar type 1 (AT1) and type 2 (AT2) cells (Fig. 1c) (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8, Reference Aspal and Zemans18). AT1 cells are the predominant epithelial cell type in the alveolus and comprise approximately 95% of the gas exchange surface of the lung, with their flattened, squamous morphology providing an ideal interface for gas exchange with the underlying vasculature (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8, Reference Aspal and Zemans18). The cuboidal AT2 cells are responsible for production of surfactant which helps reduce surface tension in the alveolar region during respiration (Ref. Reference Olajuyin, Zhang and Ji19). In addition, AT2 cells function as progenitor cells for AT1 cells, thus maintaining normal turnover of the alveolar epithelial cells during homeostasis and replenish cells which are lost after injury (Ref. Reference Aspal and Zemans18). Despite the ability of both the mucociliary and alveolar epithelium to repair and regenerate via the action of a resident adult stem/progenitor cells (i.e., BCs and AT2, respectively), the underlying ‘niche microenvironment’ (i.e., non-epithelial cell populations and extracellular matrix) of the lung plays an important role in regulating the cell differentiation and regeneration response of the epithelium via the production of key paracrine signals (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7, Reference Alysandratos, Herriges and Kotton8, Reference Aspal and Zemans18). Most of our current understanding of the mechanisms by which the lung responds to and regenerates post-injury comes from using murine lung-injury models. Despite the high conservation of lung structure and cellular composition between the human and mouse respiratory system, there are important differences (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7). These include restriction of BC in the cartilaginous rings and submucosal glands up to the trachea of the mouse lung as compared to humans, where these features extend to the distal airways. In addition, there is a reduced number of branches and complete lack of respiratory bronchioles in the mouse lung, which are the site of injury in many human lung diseases and contain distinct secretory cell populations that function as progenitors for AT2 cells (Refs Reference Basil16, Reference Kadur Lakshminarasimha Murthy17). Therefore, under certain conditions these differences may limit the translation of lung repair and regeneration mechanisms identified in mouse to the human lung. However, the abundance of genetic mouse models and the development of new technologies to assess cellular composition and the molecular responses (i.e., transcriptional and epigenetic) of specific cell types post-injury have yielded critical information and advanced our understanding of the basic mechanisms regulating lung homeostasis and regeneration (Refs Reference Whitsett1, Reference Basil2, Reference Basil and Morrisey3, Reference Zepp and Morrisey4, Reference Parekh5, Reference Hogan6, Reference Tata and Rajagopal7).

Adult human lung disease inflicts a large socio-economic burden and is a leading cause of morbidity and mortality worldwide (Refs Reference Viegi20, Reference Sahni21, Reference Czira22, Reference de Andrade, Owens and Tolle23). This includes acute lung disease in response to viral (e.g., influenza, rhinovirus (RV), SARS-CoV-2) or bacterial (e.g., Streptococcus, Haemophilus, Pseudomonas) infections and chronic respiratory diseases, such as chronic obstructive pulmonary disease (COPD), asthma, idiopathic pulmonary fibrosis (IPF), pulmonary arterial hypertension (PAH) (Refs Reference Kc24, Reference Eckhardt and Wu25, Reference Endres26, Reference Troy and Bosco27, Reference Collaborators28, Reference Harker and Lloyd29, Reference Kalil and Thomas30, Reference Kennedy31, Reference Lamers and Haagmans32, Reference Marquart33, Reference Weeks34, Reference Veetilvalappil35, Reference Agusti and Hogg36, Reference Sethi37, Reference Hewitt38, Reference Gerayeli39, Reference Owuor40, Reference Cafferkey, Coultas and Mallia41, Reference Zhu42). Many of these diseases have mortality rates comparable to most types of lung cancer (Ref. Reference Edmonds43). Development of both acute and chronic lung disease is associated with injury and alteration of the underlying architecture of the lung which disrupts its normal function (Refs Reference Basil2, Reference Basil and Morrisey3, Reference Barnes44). In the context of chronic lung disease, aberrant regeneration mechanisms lead to a failure to restore the normal architecture and cellular composition of the lung, which can eventually result in long-term lung function decline (Refs Reference Basil2, Reference Basil and Morrisey3, Reference Barnes44). Therefore, understanding the lung's response to injury and the mechanisms that regulate tissue repair and regeneration may help identify new therapeutic strategies to treat both acute and chronic lung disease.

The NOTCH signalling pathway plays an important role in lung development and regeneration of the adult lung post-injury (Refs Reference Kiyokawa and Morimoto45, Reference Xu, Moghal and Egan46, Reference Jiang, Xiao and Chen47, Reference Zong48). Signalling via the NOTCH pathway is mediated through activation of four NOTCH receptors (NOTCH1–4), with each receptor capable of regulating unique biological processes (Ref. Reference Siebel and Lendahl49). Dysregulation of the NOTCH pathway has been associated with development and pathophysiology of multiple adult lung diseases including COPD, lung cancer, asthma, IPF and PAH (Refs Reference Kiyokawa and Morimoto45, Reference Zong48, Reference Boucherat, Chakir and Jeannotte50, Reference Mori51, Reference Tilley52, Reference Buro-Auriemma53, Reference Moore54, Reference Huang, Chiu and Chiang55, Reference Morris56, Reference Gajjala and Madala57, Reference Bodas58, Reference Bodas59, Reference Jing60, Reference Reid61, Reference Vera62, Reference Carraro63, Reference Steffes64, Reference Li65, Reference Wang67, Reference Morris68). However, the specific focus of this review will be to provide a comprehensive summary of the role of NOTCH3 receptor signalling in regulating repair/regeneration of the adult lung, its association with development of lung disease and potential therapeutic strategies to target its signalling activity.

NOTCH signalling pathway

NOTCH signalling is a highly conserved cell-cell interaction signalling pathway that plays crucial roles in the development, repair and regeneration processes in the embryonic and adult lung (Refs Reference Kiyokawa and Morimoto45, Reference Xu, Moghal and Egan46, Reference Jiang, Xiao and Chen47, Reference Zong48), as well as other organ systems (Ref. Reference Siebel and Lendahl49). The mammalian NOTCH signalling pathway consists of four transmembrane receptors (NOTCH1–4) and five ligands of the Jagged (Jagged1,2 – orthologues to fly Serrate) and Delta-like (Dll1,3,4 – orthologues to fly Delta) families (Refs Reference Siebel and Lendahl49, Reference Shen, Huang and Wang69). The four NOTCH receptors share a common structure consisting of a transmembrane domain and a NOTCH extracellular domain (NECD) that is non-covalently associated with a NOTCH intracellular domain (NICD) which creates a hetero-dimeric, single-pass, transmembrane receptor (Fig. 2a) (Refs Reference Siebel and Lendahl49, Reference Shen, Huang and Wang69). The NECD contains approximately 29–36 epidermal growth factor-like domains (which enables ligand interactions) and a negative regulatory region (NRR) consisting of three Lin Notch repeats and receptor heterodimerisation domains (HD) (Refs Reference Siebel and Lendahl49, Reference Hori, Sen and Artavanis-Tsakonas70). Similarly, the NICD contains multiple domains which regulate its transcriptional activity including an RBP-Jκ-association module domain, ankyrin repeats, a transactivation domain (TAD) and a C-terminal domain rich in proline, glutamic acid, serine and threonine domain (Refs Reference Siebel and Lendahl49, Reference Hori, Sen and Artavanis-Tsakonas70). Full length NOTCH receptors are produced in the endoplasmic reticulum, and before trafficking to the plasma membrane they are proteolytically cleaved by the furin-like convertase (Site 1 or S1 cleavage) in the Golgi compartment to form a processed heterodimer (Fig. 2a) (Refs Reference Siebel and Lendahl49, Reference Hori, Sen and Artavanis-Tsakonas70). Canonical NOTCH signalling transduction is relayed via cell-to-cell contact by the direct binding of cell-bound ligand to the NECD of a receptor on a neighbouring cell (Fig. 2b) (Refs Reference Siebel and Lendahl49, Reference Hori, Sen and Artavanis-Tsakonas70). Ligand binding results in activation of the NOTCH receptor on the signal-receiving cell via multiple enzymatic cleavage events at site 2 (S2) and site 3 (S3) on the NOTCH receptor (Fig. 2a and b) (Refs Reference Siebel and Lendahl49, Reference Hori, Sen and Artavanis-Tsakonas70). S2 cleavage and release of the NECD occur via the ADAM protease, whereas S3 cleavage by the γ-secretase enzyme releases the NICD from the receptor (Ref. Reference Siebel and Lendahl49). This NICD translocates to the nucleus and interacts with other inactive transcriptional complexes (RBP-Jκ and MAML1-3) resulting in the transcription of multiple NOTCH downstream target genes. These include the HEY and HES gene families which encode basic helix-loop-helix transcription factors that typically act as repressors of transcription (Fig. 2b) (Refs Reference Siebel and Lendahl49, Reference Kovall71). The large combination of ligand–receptor interactions and cell type-specific expression of pathway components makes the canonical NOTCH signalling pathway an exceptionally versatile system that can lead to highly dynamic and diverse downstream signalling responses (Ref. Reference Siebel and Lendahl49). In addition to canonical signalling, non-canonical NOTCH signalling has been reported whereby signalling occurs either independent of ligand interaction or RBP-Jκ activation (Ref. Reference Ayaz and Osborne72). However, the role of non-canonical NOTCH signalling in lung development, repair and regeneration is poorly understood.

Fig. 2. The NOTCH signalling pathway. (a) Structure of the full-length human NOTCH receptors. The four NOTCH receptors share a common structure consisting of a NOTCH extracellular domain (NECD), transmembrane domain (TD) and a NOTCH intracellular domain (NICD). The NECD contains approximately 29–36 epidermal growth factor (EGF)-like domains, a negative regulatory region (NRR) consisting of three Lin Notch repeats (LNR) and receptor heterodimerisation domains (HD). Following the TD, the NICD contains a RBP-Jκ-association module (RAM) domain, ankyrin (ANK) repeats, a transactivation domain (TAD) and a C-terminal domain rich in proline, glutamic acid, serine and threonine (PEST) domain. The locations of the S1, S2 and S3 cleavage sites are indicated. (b) Schematic of the canonical NOTCH signalling pathway. Canonical NOTCH signalling transduction is relayed via cell-to-cell contact by the direct binding of cell-bound ligand to the NECD of a receptor on a neighbouring cell. Ligand binding results in activation of the NOTCH receptor on the signal-receiving cell via enzymatic cleavage at site 2 (S2) and site 3 (S3) on the NOTCH receptor via the ADAM protease and γ-secretase enzyme, respectively. Following cleavage of the NICD from the receptor and its release into the cytoplasm, the NICD translocates to the nucleus and interacts with transcriptional complexes (RBP-Jκ and MAML1–3) on the promoters of NOTCH target genes, resulting in their transcription.

The human NOTCH3 gene is located on chromosome 19p13.12 and encompasses 33 exons which encode for a protein composed of 2321 amino acids (Refs Reference Morris56, Reference Xiu73, 74 75). Expression of NOTCH3 has been found in multiple tissue types including the vasculature, smooth muscle, central nervous and immune system (Refs Reference Morris56, Reference Xiu73, Reference Hosseini-Alghaderi and Baron74, Reference Ceccarelli75). Relevant to the adult human and mouse lung, NOTCH3 is expressed in vascular smooth muscle cells (VSMCs), pulmonary artery smooth muscle cells (PASMCs), pericytes, fibroblasts and specific cell types of the airway epithelium (e.g., basal-intermediate and club) (Refs Reference Zong48, Reference Mori51). While deletion of Notch1 and Notch2 is embryonic lethal in mice, deletion of Notch3 does not affect embryo viability (Refs Reference Kiyokawa and Morimoto45, Reference Morris56). However, mice with deletion of Notch3 have impairment of VSMC differentiation and maturation (including the lung) that leads to alterations in the vascular structure (Refs Reference Kiyokawa and Morimoto45, Reference Morris56). In addition, the tracheal pseudostratified airway epithelium of Notch3−/− mice have increased numbers of KRT8+ undifferentiated progenitor cells (i.e., intermediate cells) compared to wild-type mice suggesting that NOTCH3 signalling in the murine airway epithelium was critical for priming of BC differentiation into club cells (Ref. Reference Mori51). In support of this, recent work from our lab demonstrated that NOTCH3 receptor signalling regulates BC to club cell differentiation in the human airway epithelium in vitro (Ref. Reference Bodas58). Lentivirus-mediated overexpression of the active NICD3 in primary human bronchial epithelial cells (HBECs) on in vitro air-liquid interface (ALI) culture promoted club cell differentiation. Furthermore, we demonstrated the NOTCH3 downstream target HEYL was important for regulating this process since siRNA-mediated knockdown of HEYL reduced club (SCGB1A1+), goblet (MUC5AC+) and ciliated cell (FOXJ1) differentiation, but lead to an increase in the number of KRT8+ intermediate cells. While mice with deletion of Notch3 display no defects in the alveolar epithelium, over-expression of NICD3 during development inhibits terminal differentiation of the alveolar epithelium (Ref. Reference Dang76). Despite sharing a similar structure to the NOTCH1 and NOTCH2 receptors, NOTCH3 displays a number of structural differences that may explain the unique aspects of NOTCH3 signalling and its regulation of lung biology compared to other NOTCH receptors (Fig. 2a) (Ref. Reference Choy77). These include differences in the NOTCH3 ECD which potentially make the receptor more vulnerable to cleavage and activation in the absence of ligand (Ref. Reference Choy77). In addition, the lack of a TAD in the NOTCH3 ICD may account for a weaker transactivation activity compared to other NOTCH ICDs.

Despite the knowledge NOTCH3 signalling is not essential for murine lung development, there is emerging evidence that dysregulation of NOTCH3 signalling in the adult human lung plays an important role in the development and pathogenesis of acute and chronic lung disease. Therefore, the remainder of this review will summarise recent new findings from ours and other groups, which highlight the pathogenic role of NOTCH3 in mediating severe respiratory diseases such as COPD, viral infections, lung cancer, asthma, IPF and PAH. Finally, we debate the potential and means of targeting NOTCH3 signalling as a therapeutic strategy for treatment of lung disease.

NOTCH3 signalling and acute or chronic lung disease

COPD and emphysema

COPD is a preventable, but life-threatening lung disease, and is the third leading cause of death in the United States (Ref. Reference Viegi20). Exposure to first and/or second-hand cigarette smoke (CS) is the leading risk factor for the initiation and progression of COPD pathophysiology, which is broadly classified into chronic bronchitis and emphysema (Refs Reference Agusti and Hogg36, Reference Tam and Sin78, Reference Higham79). Chronic bronchitis is characterised by increased inflammation of the airways and excess mucus production which leads to airflow obstruction (Refs Reference Agusti and Hogg36, Reference Tam and Sin78, Reference Higham79), whereas emphysema is a disease of the alveoli characterised by damage and permanent enlargement of the alveolar airspace, which reduces the surface area available for gas exchange (Refs Reference Agusti and Hogg36, Reference Tam and Sin78, Reference Higham79).

CS exposure is known to mediate significant changes in the cellular architecture of the mucociliary airway epithelium (termed epithelial remodelling), including BC hyperplasia, squamous metaplasia, loss of club cells and increased numbers of mucus-producing goblet cells termed ‘goblet cell metaplasia or hyperplasia’ (GCMH) (Refs Reference Rock, Randell and Hogan14, Reference Tam and Sin78, Reference Higham79). Prior studies have identified alterations at the mRNA, protein and epigenetic level for multiple NOTCH signalling pathway components in the in vivo airway epithelium of smokers with and without COPD relative to that of non-smokers (Refs Reference Boucherat, Chakir and Jeannotte50, Reference Mori51, Reference Tilley52, Reference Buro-Auriemma53). This includes decreased NOTCH3 mRNA in the airway epithelium of smokers versus non-smokers (Ref. Reference Tilley52), and decreased NOTCH3 protein levels in the airway epithelium of COPD versus non-COPD controls (Ref. Reference Mori51). While protein levels of activated NOTCH3 receptor (i.e., NICD3) were not assessed in these studies, these data suggest that reduced levels of NOTCH3 receptor (and its downstream signalling) may contribute to the development of airway epithelial remodelling associated with CS exposure and COPD (Refs Reference Rock, Randell and Hogan14, Reference Tam and Sin78, Reference Higham79). In support of this, our recent study observed decreased expression of the NOTCH3 downstream target HEYL in HBECs from COPD versus normal (non-COPD) donors which correlated with the impaired differentiation capacity of COPD HBECs on in vitro ALI culture (Ref. Reference Bodas58). Furthermore, we demonstrated that lentivirus-mediated overexpression of HEYL in COPD HBECs promoted differentiation into club, goblet and ciliated cells. Combined, these data suggest the impaired capacity of COPD cells to generate a normal airway epithelium is a reversible phenotype that can be regulated by the NOTCH3 target HEYL.

In contrast to the above findings that suggest decreased NOTCH3 signalling may contribute to the development of airway epithelial remodelling associated with CS exposure and COPD, our recent study demonstrated that in vitro CS exposure activates NOTCH3 signalling to promote development of GCMH in both non-smoker and COPD airway epithelial cells (Ref. Reference Bodas59). Cigarette smoke extract (CSE) exposure of in vitro ALI cultures of differentiated human mucociliary airway epithelium generated from primary non-smoker and COPD smoker human HBECs resulted in a decrease in the number of SCGB1A1+ club cells with a parallel increase in MUC5AC+ goblet cells, characteristic of GCMH (Ref. Reference Bodas59). Development of CSE-dependent GCMH corresponded with increased activation of the NOTCH3 receptor (i.e., increased NICD3 levels and nuclear localisation) with no change in the expression of NOTCH3 mRNA, suggesting that CSE regulates NOTCH3 protein levels post-transcriptionally. Importantly, inhibition of NOTCH3 signalling via treatment with the γ-secretase inhibitor dibenzazepine (DBZ) or siRNA-mediated knockdown of NOTCH3 expression suppressed CSE-induced GCMH phenotype. In support of our findings, CS exposure increased the activation of NOTCH3 protein in human lung adenocarcinoma both in vitro and in vivo (Ref. Reference Cheng80). Furthermore, Gomi et al. (Ref. Reference Gomi81) demonstrated that long-term (28 days) over-expression of NICD3 in normal HBECs on in vitro ALI culture induced a phenotype characteristic of GCMH. Therefore, targeting NOTCH3 activity could be a novel therapeutic strategy to control GCMH in smokers with and without COPD. However, based on the knowledge that airway epithelium of smokers and COPD patients contain reduced levels of NOTCH3 mRNA and protein relative to healthy controls (Ref. Reference Tilley52), future work is required to better understand the cell type-specific expression pattern of NOTCH3 and the mechanisms regulating its activation state and kinetics in the context of COPD-associated airway epithelial remodelling.

Although, there is no report showing the direct role of NOTCH3 signalling in COPD-associated emphysema, a recent study described that enhanced NOTCH3 signalling contributes to Marfan syndrome-associated pulmonary emphysema in mice (Ref. Reference Jespersen82). Marfan syndrome is a genetic disorder caused by mutations in the fibrillin-1 gene (Refs Reference Jespersen82, Reference Sakai83, Reference Kainulainen84). Apart from other systemic effects, one of the major disease manifestations is altered lung function and pulmonary emphysema (Refs Reference Jespersen82, Reference Neptune85, Reference Uriarte86). The mouse model of Marfan syndrome (mgR mice) shows a progressive development of airspace enlargement (emphysematous changes), which correlates with an increase in NOTCH3 activation (but not NOTCH1, 2 or 4). Moreover, treatment with DAPT, a γ-secretase inhibitor which blocks global NOTCH signalling, prevented emphysema development in mgR mice, while decreasing NOTCH3 activation, thereby suggesting that NOTCH3 activation drives emphysema development in mgR mice (Ref. Reference Jespersen82). However, the use of a global NOTCH signalling inhibitor questions the specificity of the NOTCH3-dependent effects. Therefore, future studies using strategies to specifically block NOTCH3 signalling in the mgR mouse model are required to strengthen and confirm the pathogenic role of NOTCH3 activation in driving emphysema development in Marfan syndrome.

Viral exacerbations and COPD

Acute exacerbations caused by viral infections can result in significant morbidity, mortality and hospitalisations in COPD subjects (Refs Reference Sethi37, Reference Hewitt38, Reference Gerayeli39, Reference Singanayagam87). RV is a common respiratory pathogen associated with increased GCMH in COPD subjects, resulting in severe and prolonged respiratory distress and airflow obstruction (Refs Reference Owuor40, Reference Cafferkey, Coultas and Mallia41, Reference Zhu42, Reference Jing60). These symptoms are attributed to an increase in both virus-induced mucin production, and an increase in number of mucus-producing secretory (goblet) cells (Refs Reference Owuor40, Reference Cafferkey, Coultas and Mallia41, Reference Zhu42, Reference Jing60, Reference Singanayagam87). A recent study by Jing et al. (Ref. Reference Jing60) showed that in vitro RV infection of COPD cells differentiated on ALI culture resulted in the activation of NOTCH3 and its downstream target, HEY1. This NOTCH3-HEY1 activation correlated with increased mucin gene expression, with a parallel increase in the numbers of goblet cells (i.e., GCMH). Furthermore, they demonstrate that inhibition of NOTCH3 signalling via treatment with the γ-secretase inhibitor DAPT or shRNA-mediated knockdown of NOTCH3 expression suppressed RV-induced GCMH in COPD cells. Interestingly, RV infection of ALI differentiated epithelium from normal cells did not lead to increased NOTCH3 signalling, and development of GCMH, suggesting that COPD cells have inherent or intrinsic changes that make them susceptible to RV-dependent induction of NOTCH3 signalling. In contrast to our findings with CSE (Ref. Reference Bodas59), Jing et al. do not observe a change in the number of club cells upon RV infection, suggesting that the increase in the number of goblet cells may result from direct differentiation of BC into goblet cells, whereas CSE exposure leads to differentiation of club to goblet cells. Therefore, future studies, which could include lineage tracing experiments, are required to better understand the context-dependent mechanisms driving NOTCH3 activation in response to environmental stimuli (i.e., CS and viral) and the specific cell types involved in the development of GCMH.

Lung cancer

Lung cancer is among the predominant causes of death worldwide and takes the top spot in cancer-related deaths (Refs Reference Thandra88, Reference Barta, Powell and Wisnivesky89). Both COPD and lung cancer are CS-related diseases and are described as risk factors of each other, while commonly occurring as co-morbid conditions (Refs Reference Media90, Reference Husebo91, Reference Liao92). Since NOTCH signalling is one of the key regulators of cell fate, with intricate control over cell proliferation, survival, differentiation and apoptosis, it is unsurprising that NOTCH is strongly related to lung cancer (Refs Reference Moore54, Reference Li93, Reference Barse and Bocchetta94, Reference Sparaneo, Fabrizio and Muscarella95, Reference Katoh and Katoh96). Although NOTCH signalling is implicated in both small cell lung cancer (SCLC) and non-small cell lung carcinoma (NSCLC), NOTCH3 is primarily over-expressed in NSCLC (Ref. Reference Dang97), which constitutes almost 85% of all lung cancer cases (Ref. Reference Li93). Furthermore, CS exposure increased the activation of NOTCH3 protein in human lung adenocarcinoma (a subtype of NSCLC) both in vitro and in vivo (Ref. Reference Cheng80). Interestingly, NOTCH3 plays a tumour-promoting role in NSCLC, while it acts as a tumour-suppressor in SCLC, suggesting cell type-specific functional roles of NOTCH3 in lung cancer (Ref. Reference Li93). A 5-year study to evaluate NOTCH3 expression in NSCLC patients undergoing surgical treatment showed that NOTCH3 was highly expressed in 51% of the NSCLC patients (Ref. Reference Ye98). Moreover, survival of patients with higher expression of NOTCH3 was shorter as compared to patients with normal NOTCH3 levels, suggesting a direct correlation of NOTCH3 expression with lung cancer-related mortality (Ref. Reference Ye98). Mechanistically, NOTCH3 signalling has been implicated in lung cancer metastasis (Refs Reference Li93, Reference Katoh and Katoh96, Reference Li99). Activation of WNT signalling via Wnt3a ligand treatment upregulated the mRNA and protein expression of NOTCH3, and its downstream targets HEYL and HES1, while promoting cell invasion and anchorage-independent growth (Ref. Reference Li100). Additionally, knockdown of NOTCH3 abrogated the effects of Wnt3a treatment on cell invasion and epithelial mesenchymal transition (EMT)-like morphological changes, suggesting NOTCH3 is required for Wnt3a-mediated metastatic effects in NSCLC cells (Ref. Reference Li100). Overall, these studies provide strong clinical and mechanistic evidence of the pathogenic role of NOTCH3 signalling in NSCLC, and strengthen the rationale for therapeutically targeting its activity to treat the disease.

Asthma

Asthma is an allergen-induced chronic lung condition marked by chronic airway inflammation, mucus hypersecretion, airway remodelling and obstruction, and increased airway hyper-reactivity (Refs Reference Kudo, Ishigatsubo and Aoki101, Reference Al Heialy, Ramakrishnan and Hamid102). A recent study by Reid et al. (Ref. Reference Reid61) identified a potential role of NOTCH3 hyperactivation in mucus production associated with asthma. The authors found that NOTCH3 protein levels and nuclear staining (i.e., indicative of NOTCH3 activation) were increased in human bronchial sections from asthma subjects as compared to non-asthma. In support of this, NOTCH3 levels (mRNA and NICD3 protein levels) were similarly elevated in the in vitro ALI-differentiated airway epithelium generated from HBECs of asthmatics as compared to HBECs from non-asthmatics. In addition, increased NOTCH3 levels in asthmatic epithelium appeared more intense around areas of MUC5AC+ goblet cells. The authors further demonstrate that inhibition of NOTCH signalling using DBZ reduced in vitro MUC5AC expression and secretion in ALI cultures and subsequent siRNA-mediated knockdown of NOTCH3 expression showed a decrease in MUC5AC production. Combined, these data suggest that NOTCH3 activation in the airway epithelium drives MUC5AC expression and secretion and thus contributes to the increased mucus production in asthmatic airways. However, in contrast to the above study, a recent paper by Carrer et al. (Ref. Reference Carrer103) showed that blocking NOTCH2 (but not NOTCH3) activation using antisense oligonucleotides (ASOs) reduced house dust mite (HDM) induced GCMH in adult mouse lungs. The differences observed between these studies may reflect differences in the underlying mechanisms driving asthma-associated GCMH versus HDM-associated GCMH, and species-specific differences between the human and mouse airway epithelium, including the cell type-specific expression of NOTCH receptors and ligands (Refs Reference Basil and Morrisey3, Reference Kiyokawa and Morimoto45).

In addition to its role in regulating the airway epithelium, NOTCH signalling also regulates the balance of T-helper (Th) 1 and Th2 immune cells, which plays a crucial role in the pathogenesis of allergic asthma (Refs Reference Zong48, Reference Huang, Chiu and Chiang55, Reference Kang104, Reference Gu105). Global suppression of NOTCH signalling using γ-secretase inhibitors reduces airway inflammation in the ovalbumin (OVA)-induced murine model, suggesting that NOTCH signalling may play a pro-pathogenic role in asthma (Ref. Reference Kang104). A later study identified that the imbalance of Th17/Treg (regulatory) cells in children with allergic asthma correlated with an increase in NOTCH1 activity (Ref. Reference Li106). Furthermore, in a murine model of OVA-induced asthma, NOTCH signalling inhibition using γ-secretase inhibitors suppressed Th17 cell responses along with decreasing asthma features, suggesting the direct role of NOTCH signalling in regulating Th17 cell differentiation (Ref. Reference Zhang107). However, the underlying complexity in the role of NOTCH signalling in asthma is evident by the findings that constitutive activation of NOTCH3 signalling promotes the generation and expansion of asthma-protective Treg cells (Refs Reference Zong48, Reference Anastasi108). Additionally, over-activation of NICD3 in activated CD4 + T cells promoted Th1 differentiation, which is known to elicit a protective T cell response in asthma (Ref. Reference Maekawa109). Overall, these studies highlight the complexity of NOTCH signalling in asthma pathogenesis, where it is evident that different NOTCH receptors (including NOTCH3) regulate pathogenic or asthma-protective responses in a context-dependent manner.

IPF

IPF is a progressive, irreversible chronic lung disease with a high fatality rate (Refs Reference Jeganathan, Smith and Sathananthan110, Reference Mei111, Reference Martinez112). The disease is caused in response to repeated injury which leads to damage and subsequent destruction of the alveolar compartment which reduces the gas exchange capabilities of the lung (Refs Reference Mei111, Reference Martinez112). Pathological features of IPF include impaired alveolar re-epithelisation, elevated extracellular matrix (ECM) deposition, increased myofibroblast proliferation, parenchymal remodelling and the appearance of honeycomb cysts (composed of airway epithelial BC and mucin producing secretory cells) in the distal airways, which ultimately combine to cause life-threatening destruction of lung architecture (Refs Reference Vera62, Reference Chilosi113, Reference Kristensen114, Reference Chambers and Mercer115).

In general, activation of NOTCH signalling via different receptors is associated with factors that promote pulmonary fibrosis, such as myofibroblast differentiation, EMT, activation of TGFβ and Wnt/β-catenin signalling, and increased proliferation and de-differentiation of alveolar epithelial type II cells (Refs Reference Vera62, Reference Zhang116, Reference Hu117, Reference Zhou118, Reference Chanda119, Reference Hu and Phan120). However, a recent study by Carraro et al. (Ref. Reference Carraro63) characterizing the transcriptome of single cells from normal human lung versus lung tissue of patients with end-stage IPF identified alterations in the subsets of airway BCs, with expansion of a secretory primed population of BCs in the IPF lung that is capable of differentiating into mature mucus-producing goblet cells. The authors further demonstrate that NOTCH3 signalling activity is required to maintain this population of secretory primed BCs, and inhibition of NOTCH3 signalling with a NOTCH3-specific blocking antibody promoted their differentiation into goblet cells. These findings contrast with the previous studies from our lab demonstrating that inhibition of NOTCH3 signalling prevented CSE-mediated induction of goblet cell differentiation (Ref. Reference Bodas59). Potential reasons for the discrepancy between these studies maybe related to differences in the in vitro ALI culture systems and time points analysed, the method of inhibiting NOTCH3 activity (i.e., blocking antibody versus siRNA) and HBEC populations (i.e., cell sorted for specific populations versus no cell sorting) used for ALI culture which may respond differentially to either NOTCH3 inhibition or CSE treatment. Therefore, further studies are required to clarify the role of NOTCH3-dependent differentiation of individual airway epithelial cell populations and the timing of NOTCH3 signalling events that regulate these processes. In addition to its role in regulating airway epithelial cell differentiation in the context of IPF, a recent report by Vera et al. (Ref. Reference Vera62) showed the specific role of NOTCH3 in fibroblast activation and development of pulmonary fibrosis. The authors demonstrate that bleomycin treated Notch3−/− mice have much smaller numbers of myofibroblasts and were protected from development of pulmonary fibrosis. More importantly, Notch3−/− mice showed less collagen deposition and improved lung function post bleomycin treatment, suggesting that targeting NOTCH3 might be a useful strategy to mitigate the lung function decline in IPF. Although this study provides significant evidence of the role of NOTCH3 in IPF development, it does not delve into the possible upstream causes of NOTCH3 activation. However, a previous study by Lai et al. (Ref. Reference Lai121) demonstrated that reactive oxygen species-dependent activation of p38, JNK1/2 and NOTCH3 promoted basal and TGF-β1 induced differentiation and expression of ECM proteins in primary human lung fibroblasts (IMR-90 cells) in vitro. Moreover, TGF-β1 induced the expression of α-smooth muscle actin (a marker of myofibroblasts) and NOTCH3, both of which were suppressed by treatment with DAPT or NOTCH3-specific siRNA. Overall, these studies provide a strong rationale for targeting NOTCH3 signalling as a potential therapeutic strategy in controlling IPF.

PAH

PAH is a rare, progressive and devastating disease in which there is high blood pressure due to thickening and narrowing of the small arteries in the lungs (Refs Reference Gelzinis122, Reference Hassoun123). The blockage in the pulmonary vessels may progress to right-side heart failure which is the primary cause of high morbidity and mortality associated with PAH (Refs Reference Luna-Lopez, Ruiz Martin and Escribano Subias124, Reference Rajagopal and Yu125, Reference Naeije, Richter and Rubin126). At the cellular level, the main changes in PAH include proliferation of fibroblasts, infiltration of immune cells and proliferation of PASMCs (Refs Reference Rajagopal and Yu125, Reference Tobal127, Reference Luo and Qiu128, Reference Lyle, Davis and Brozovich129, Reference Christou and Khalil130). The above factors mediate the development of a vascular remodelling phenotype, called ‘neointimal lesions’, resulting in the elevation of pulmonary vascular resistance and ultimately heart failure (Refs Reference Steffes64, Reference Ivy131, Reference Li132, Reference Tsutsumi133). There have been several studies investigating the role of NOTCH3 signalling in PAH, which are reviewed in detail by Morris et al. (Ref. Reference Morris56). A report by Li et al. (Ref. Reference Li65) showed that PAH is characterised by elevated expression of NOTCH3 in PASMCs, and the severity of disease in both humans and rodents correlates with the amount of NOTCH3 present in the lungs. The development of neointimal lesions observed in PAH is thought to originate from the massive clonal expansion of a small number of smooth muscle cells, termed as the neointimal founder cells (Ref. Reference Steffes64). A recent and interesting study found that a minor subpopulation of NOTCH3 + VSMCs acts as the neointimal cell of origin in multiple mouse models of PAH (Ref. Reference Steffes64). Furthermore, studies demonstrate that overexpression of NOTCH ligand JAGGED-1 (JAG1) in human small PASMCs promotes their proliferation through activation of NOTCH3 signalling (Ref. Reference Zhang66). Inhibition of NOTCH signalling using DBZ abrogates the selection of this NOTCH3-marked neointimal founder cell subpopulation, resulting in significant improvement in pulmonary artery pressure in mouse models of PAH (Ref. Reference Steffes64). Therefore, identification of a distinct subpopulation of NOTCH3+ cells among normal tissues, which specifically generates neointimal lesions, provides novel avenues for therapeutic development in PAH.

Exposure to chronic hypoxia results in development of the vascular remodelling phenotype implicated in PAH (Refs Reference Pak134, Reference Rowan135). In sync with the disease promoting role of NOTCH3 in PAH, Notch3+/− and Notch3−/− mice were resistant to PAH development compared to wild-type mice after 6 weeks of chronic hypoxia (Ref. Reference Li65). Furthermore, over-expression of the activated intracellular domain of NOTCH3 (NICD3) led to proliferation of PASMCs, which correlated with increased expression of the NOTCH downstream target Hes1, and decreased p27Kip1 expression (Ref. Reference Li65). The authors also confirmed that HES1 lies downstream of NOTCH3 signalling, as siRNA-mediated knockdown of HES1, prevented the proliferative effects of NICD3 over-expression. A more recent study (Ref. Reference Wang67) provides evidence that elevated levels of NOTCH3 in PAH are regulated by sphingosine-1-phosphate-dependent signalling via the sphingosine-1-phosphate receptor 2. Moreover, a genetic basis of NOTCH3 activation in PAH was demonstrated by a recent study which showed that only the male mice with CADASIL (cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy) causing mutation R169C (TgNotch3R169C), demonstrate gain-of-function NOTCH3 activation and develop PAH-like features (Ref. Reference Morris68). Thus, the NOTCH3 R169C mutation may be associated with PAH susceptibility in males.

The above studies provide substantial evidence of the pathogenic role of NOTCH3 activation in PAH, thus making it a potential therapeutic target to control PAH. In support of this, a recent study by Zhang et al. (Ref. Reference Zhang66) using both mouse and rat models of PAH demonstrated that treatment with anti-NOTCH3 antibody (Ab 28042) which inhibits JAG1-dependent activation of NOTCH3 signalling, reversed PAH. Furthermore, treatment of animals with the anti-NOTCH3 antibody did not lead to local or systemic toxicity, suggesting that blocking JAG1-dependent activation of NOTCH3 signalling could be a promising therapeutic strategy for treating patients with PAH.

Therapeutic strategies for targeting NOTCH3 signalling

Evidence provided in this review highlights the involvement of NOTCH3 signalling in the development of acute and chronic lung disease. Therefore, strategies to specifically target NOTCH3 signalling provide an attractive therapeutic option to treat and control lung disease pathogenesis (Refs Reference Bodas59, Reference Jing60, Reference Reid61, Reference Vera62, Reference Carraro63, Reference Steffes64, Reference Li65, Reference Morris68, Reference Lin136). Several clinical studies have used γ-secretase inhibitors to block NOTCH signalling in various human diseases (Refs Reference Konishi137, Reference McCaw138, Reference Dobrowolska Zakaria and Vassar139, Reference Cook140), but the strategy lacks specificity for individual receptors, which can lead to global suppression of signalling and toxic side effects (Refs Reference Doody141, Reference Penninkilampi, Brothers and Eslick142, Reference Hur143, Reference Christopoulos144). Therefore, more specific strategies to target NOTCH3 are required. Antibody-based inhibition is a clinically proven therapeutic strategy to selectively inhibit specific NOTCH receptor signalling (Refs Reference Christopoulos144, Reference Allen and Maillard145). To this end, blocking antibodies which suppress NOTCH3 activation via targeting the NOTCH3 NRR and HD (Ref. Reference Li146), or NOTCH3 ligand interactions (Ref. Reference Zhang66) have been successfully developed. These antibodies have been shown to provide anti-cancer activity and reverse pathology associated with IPF and PAH using in vitro and in vivo pre-clinical models of disease (Refs Reference Zhang66, Reference Christopoulos144). While blocking NOTCH ligands maybe less specific than directly targeting the receptor, this approach has proved successful in a pre-clinical murine asthma model, whereby blocking antibodies targeting the JAG1 and JAG2 ligands reversed OVA-induced GCMH (Ref. Reference Lafkas147).

In addition to blocking antibodies, targeting of NOTCH3 expression with ASOs may provide an alternative strategy to specifically inhibit NOTCH3 signalling (Refs Reference Carrer103, Reference Canalis148, Reference Canalis149). Down-regulation of Notch3 expression via systemic administration of Notch3-specific ASOs in a Notch3 gain-of function mutation (Notch3em1Ecan) mouse model of lateral meningocele syndrome ameliorates cortical osteopenia associated with the mice (Ref. Reference Canalis149). Therefore, while targeting of Notch3 expression with ASOs failed to reduce HDM-induced GCMH in adult mouse lungs (Ref. Reference Carrer103), this therapeutic approach may be more applicable for lung diseases like IPF and PAH where the role of NOTCH3 signalling in disease pathogenesis is more clearly defined.

Conclusions

In summary, there is rapidly accumulating evidence that alteration of NOTCH3 signalling in the adult human lung plays an important role in the development and pathogenesis of multiple acute and chronic lung diseases, including COPD, viral infections, lung cancer, asthma, IPF and PAH. Furthermore, both in vitro and in vivo pre-clinical models of lung disease have been utilised to successfully demonstrate the potential of targeting NOTCH3 signalling activity as a viable therapeutic strategy for treatment of human lung disease. However, it is important to study, modulate and target NOTCH3 signalling in a cell-specific manner in order to prevent off-target effects. Thus, further investigations are required to better understand at the disease and cell-specific level, the precise mechanisms whereby dysregulation NOTCH3 signalling leads to pathogenic outcomes. Success in these studies should lead to further improvement of existing therapeutic strategies to target NOTCH3 signalling and ultimately facilitate the development of new treatments for human lung disease.

Acknowledgements

This work was supported by the following grants awarded to Matthew S. Walters: NIH/NIGMS COBRE (GM103636, Project 4), Oklahoma Center for Adult Stem Cell Research (OCASCR), a program of TSET, Grant, a Presbyterian Health Foundation (PHF) New Investigator Seed Grant and a PHF Seed Grant; Harry Karmouty-Quintana: NIH/NHLBI (R01-HL138510 and R01-HL157100) and Peter F. Vitiello: NIH/NHLBI (R01-HL135112).

Author contributions

M.B. and M.S.W: conceptualisation of the manuscript, writing of the original draft and editing. B.S., H.K-Q and P.F.V: critical review and editing. All the authors approved the final version of the manuscript for publication.

Financial support

The funders had no role in the decision to publish or preparation of the manuscript.

Conflicts of interest

All the authors declare they have no conflicts of interest in relation to the subject matter or materials discussed in this manuscript.

References

Whitsett, JA et al. (2019) Building and regenerating the lung cell by cell. Physiological reviews 99, 513554.CrossRefGoogle ScholarPubMed
Basil, MC et al. (2020) The cellular and physiological basis for lung repair and regeneration: past, present, and future. Cell Stem Cell 26, 482502.CrossRefGoogle ScholarPubMed
Basil, MC and Morrisey, EE (2020) Lung regeneration: a tale of mice and men. Seminars in Cell & Developmental Biology 100, 88100.CrossRefGoogle ScholarPubMed
Zepp, JA and Morrisey, EE (2019) Cellular crosstalk in the development and regeneration of the respiratory system. Nature Reviews Molecular Cell Biology 20, 551566.CrossRefGoogle ScholarPubMed
Parekh, KR et al. (2020) Stem cells and lung regeneration. American Journal of Physiology. Cell Physiology 319, C675C693.CrossRefGoogle ScholarPubMed
Hogan, BL et al. (2014) Repair and regeneration of the respiratory system: complexity, plasticity, and mechanisms of lung stem cell function. Cell Stem Cell 15, 123138.CrossRefGoogle ScholarPubMed
Tata, PR and Rajagopal, J (2017) Plasticity in the lung: making and breaking cell identity. Development 144, 755766.CrossRefGoogle ScholarPubMed
Alysandratos, KD, Herriges, MJ and Kotton, DN (2021) Epithelial stem and progenitor cells in lung repair and regeneration. Annual Review of Physiology 83, 529550.CrossRefGoogle ScholarPubMed
Kandathil, A and Chamarthy, M (2018) Pulmonary vascular anatomy & anatomical variants. Cardiovascular Diagnosis and Therapy 8, 201207.CrossRefGoogle ScholarPubMed
Gil, J (1988) The normal lung circulation. State of the art. Chest 93, 80S82S.Google ScholarPubMed
Elliott, FM and Reid, L (1965) Some new facts about the pulmonary artery and Its branching pattern. Clinical Radiology 16, 193198.CrossRefGoogle ScholarPubMed
Deprez, M et al. (2020) A single-cell atlas of the human healthy airways. American Journal of Respiratory and Critical Care Medicine 202, 16361645.CrossRefGoogle ScholarPubMed
Busch, SM, Lorenzana, Z and Ryan, AL (2021) Implications for extracellular matrix interactions with human lung basal stem cells in lung development, disease, and airway modeling. Frontiers in Pharmacology 12, 645858.CrossRefGoogle ScholarPubMed
Rock, JR, Randell, SH and Hogan, BL (2010) Airway basal stem cells: a perspective on their roles in epithelial homeostasis and remodeling. Disease Models & Mechanisms 3, 545556.CrossRefGoogle ScholarPubMed
Aros, CJ et al. (2020) Distinct spatiotemporally dynamic Wnt-secreting niches regulate proximal airway regeneration and aging. Cell Stem Cell 27, 413429, e4.CrossRefGoogle ScholarPubMed
Basil, MC et al. (2022) Human distal airways contain a multipotent secretory cell that can regenerate alveoli. Nature 604, 120126.CrossRefGoogle ScholarPubMed
Kadur Lakshminarasimha Murthy, P et al. (2022) Human distal lung maps and lineage hierarchies reveal a bipotent progenitor. Nature 604, 111119.CrossRefGoogle ScholarPubMed
Aspal, M and Zemans, RL (2020) Mechanisms of ATII-to-ATI cell differentiation during lung regeneration. International Journal of Molecular Sciences 21(9), 3188.CrossRefGoogle ScholarPubMed
Olajuyin, AM, Zhang, X and Ji, HL (2019) Alveolar type 2 progenitor cells for lung injury repair. Cell Death Discovery 5, 63.CrossRefGoogle ScholarPubMed
Viegi, G et al. (2020) Global burden of chronic respiratory diseases. Journal of Aerosol Medicine and Pulmonary Drug Delivery 33, 171177.CrossRefGoogle ScholarPubMed
Sahni, S et al. (2017) Socioeconomic status and its relationship to chronic respiratory disease. Advances in Respiratory Medicine 85, 97108.CrossRefGoogle ScholarPubMed
Czira, A et al. (2022) A systematic literature review of burden of illness in adults with uncontrolled moderate/severe asthma. Respiratory Medicine 191, 106670.CrossRefGoogle ScholarPubMed
de Andrade, JA, Owens, GM and Tolle, L (2021) Idiopathic pulmonary fibrosis: exploring the clinical and economic implications of the evolving treatment landscape. The American Journal of Managed Care 27(suppl. 7), S131S137.Google ScholarPubMed
Kc, R et al. (2018) The role of environmental exposure to non-cigarette smoke in lung disease. Clinical and Translational Medicine 7, 39.CrossRefGoogle ScholarPubMed
Eckhardt, CM and Wu, H (2021) Environmental exposures and lung aging: molecular mechanisms and implications for improving respiratory health. Current Environmental Health Reports 8, 281293.CrossRefGoogle ScholarPubMed
Endres, A et al. (2022) Pseudomonas aeruginosa affects airway epithelial response and barrier function during rhinovirus infection. Frontiers in Cellular and Infection Microbiology 12, 846828.CrossRefGoogle ScholarPubMed
Troy, NM and Bosco, A (2016) Respiratory viral infections and host responses; insights from genomics. Respiratory Research 17, 156.CrossRefGoogle ScholarPubMed
Collaborators, GBDCRD (2020) Prevalence and attributable health burden of chronic respiratory diseases, 1990–2017: a systematic analysis for the Global Burden of Disease Study 2017. The Lancet. Respiratory Medicine 8, 585596.Google Scholar
Harker, JA and Lloyd, CM (2021) Overlapping and distinct features of viral and allergen immunity in the human lung. Immunity 54, 617631.CrossRefGoogle ScholarPubMed
Kalil, AC and Thomas, PG (2019) Influenza virus-related critical illness: pathophysiology and epidemiology. Critical Care 23, 258.CrossRefGoogle ScholarPubMed
Kennedy, JL et al. (2012) Pathogenesis of rhinovirus infection. Current Opinion in Virology 2, 287293.CrossRefGoogle ScholarPubMed
Lamers, MM and Haagmans, BL (2022) SARS-CoV-2 pathogenesis. Nature Reviews Microbiology 20, 270284.CrossRefGoogle ScholarPubMed
Marquart, ME (2021) Pathogenicity and virulence of Streptococcus pneumoniae: cutting to the chase on proteases. Virulence 12, 766787.CrossRefGoogle Scholar
Weeks, JR et al. (2021) The role of non-typeable Haemophilus influenzae biofilms in chronic obstructive pulmonary disease. Frontiers in Cellular and Infection Microbiology 11, 720742.CrossRefGoogle ScholarPubMed
Veetilvalappil, VV et al. (2022) Pathogenic arsenal of Pseudomonas aeruginosa: an update on virulence factors. Future Microbiology 17, 465481.CrossRefGoogle ScholarPubMed
Agusti, A and Hogg, JC (2019) Update on the pathogenesis of chronic obstructive pulmonary disease. New England Journal of Medicine 381, 12481256.CrossRefGoogle Scholar
Sethi, S (2010) Infection as a comorbidity of COPD. European Respiratory Journal 35, 12091215.CrossRefGoogle ScholarPubMed
Hewitt, R et al. (2016) The role of viral infections in exacerbations of chronic obstructive pulmonary disease and asthma. Therapeutic Advances in Respiratory Disease 10, 158174.CrossRefGoogle ScholarPubMed
Gerayeli, FV et al. (2021) COPD and the risk of poor outcomes in COVID-19: a systematic review and meta-analysis. EClinicalMedicine 33, 100789.CrossRefGoogle ScholarPubMed
Owuor, N et al. (2017) Rhinovirus and COPD airway epithelium. Pulmonary and Critical Care Medicine 2(3), 10.15761.CrossRefGoogle ScholarPubMed
Cafferkey, J, Coultas, JA and Mallia, P (2020) Human rhinovirus infection and COPD: role in exacerbations and potential for therapeutic targets. Expert Review of Respiratory Medicine 14, 777789.CrossRefGoogle ScholarPubMed
Zhu, J et al. (2020) Bronchial mucosal inflammation and illness severity in response to experimental rhinovirus infection in COPD. Journal of Allergy and Clinical Immunology 146, 840850, e7.CrossRefGoogle ScholarPubMed
Edmonds, P et al. (2001) A comparison of the palliative care needs of patients dying from chronic respiratory diseases and lung cancer. Palliative Medicine 15, 287295.CrossRefGoogle ScholarPubMed
Barnes, PJ et al. (2021) Chronic lung diseases: prospects for regeneration and repair. European Respiratory Review 30(159), 200213.CrossRefGoogle ScholarPubMed
Kiyokawa, H and Morimoto, M (2020) Notch signaling in the mammalian respiratory system, specifically the trachea and lungs, in development, homeostasis, regeneration, and disease. Development Growth & Differentiation 62, 6779.CrossRefGoogle ScholarPubMed
Xu, K, Moghal, N and Egan, SE (2012) Notch signaling in lung development and disease. Advances in Experimental Medicine and Biology 727, 8998.CrossRefGoogle ScholarPubMed
Jiang, J, Xiao, K and Chen, P (2017) NOTCH signaling in lung diseases. Experimental Lung Research 43, 217228.CrossRefGoogle ScholarPubMed
Zong, D et al. (2016) Notch signaling in lung diseases: focus on Notch1 and Notch3. Therapeutic Advances in Respiratory Disease 10, 468484.CrossRefGoogle ScholarPubMed
Siebel, C and Lendahl, U (2017) Notch signaling in development, tissue homeostasis, and disease. Physiological Reviews 97, 12351294.CrossRefGoogle ScholarPubMed
Boucherat, O, Chakir, J and Jeannotte, L (2012) The loss of Hoxa5 function promotes notch-dependent goblet cell metaplasia in lung airways. Biology Open 1, 677691.CrossRefGoogle ScholarPubMed
Mori, M et al. (2015) Notch3-Jagged signaling controls the pool of undifferentiated airway progenitors. Development 142, 258267.CrossRefGoogle ScholarPubMed
Tilley, AE et al. (2009) Down-regulation of the notch pathway in human airway epithelium in association with smoking and chronic obstructive pulmonary disease. American Journal of Respiratory and Critical Care Medicine 179, 457466.CrossRefGoogle ScholarPubMed
Buro-Auriemma, LJ et al. (2013) Cigarette smoking induces small airway epithelial epigenetic changes with corresponding modulation of gene expression. Human Molecular Genetics 22, 47264738.CrossRefGoogle ScholarPubMed
Moore, G et al. (2020) Top Notch targeting strategies in cancer: a detailed overview of recent insights and current perspectives. Cells 9(6), 1503.CrossRefGoogle ScholarPubMed
Huang, MT, Chiu, CJ and Chiang, BL (2019) Multi-faceted Notch in allergic airway inflammation. International journal of molecular sciences 20(14), 3508.CrossRefGoogle ScholarPubMed
Morris, HE et al. (2019) Notch3 signalling and vascular remodelling in pulmonary arterial hypertension. Clinical Science 133, 24812498.CrossRefGoogle ScholarPubMed
Gajjala, PR and Madala, SK (2021) Notch3: a New culprit in fibrotic lung disease. American Journal of Respiratory Cell and Molecular Biology 64, 403404.CrossRefGoogle ScholarPubMed
Bodas, M et al. (2021) The NOTCH3 downstream target HEYL Is required for efficient human airway basal cell differentiation. Cells 10(11), 3215.CrossRefGoogle ScholarPubMed
Bodas, M et al. (2021) Cigarette smoke activates NOTCH3 to promote goblet cell differentiation in human airway epithelial cells. American Journal of Respiratory Cell and Molecular Biology 64, 426440.CrossRefGoogle ScholarPubMed
Jing, Y et al. (2019) NOTCH3 contributes to rhinovirus-induced goblet cell hyperplasia in COPD airway epithelial cells. Thorax 74, 1832.CrossRefGoogle ScholarPubMed
Reid, AT et al. (2020) Blocking Notch3 signaling abolishes MUC5AC production in airway epithelial cells from individuals with asthma. American Journal of Respiratory Cell and Molecular Biology 62, 513523.CrossRefGoogle ScholarPubMed
Vera, L et al. (2021) Notch3 deficiency attenuates pulmonary fibrosis and impedes lung-function decline. American Journal of Respiratory Cell and Molecular Biology 64, 465476.CrossRefGoogle ScholarPubMed
Carraro, G et al. (2020) Single cell reconstruction of human basal cell diversity in normal and IPF lung. American Journal of Respiratory and Critical Care Medicine 202(11), 1540–1550.CrossRefGoogle Scholar
Steffes, LC et al. (2020) A Notch3-marked subpopulation of vascular smooth muscle cells is the cell of origin for occlusive pulmonary vascular lesions. Circulation 142, 15451561.CrossRefGoogle ScholarPubMed
Li, X et al. (2009) Notch3 signaling promotes the development of pulmonary arterial hypertension. Nature Medicine 15, 12891297.CrossRefGoogle ScholarPubMed
Zhang, Y et al. (2022) JAGGED-NOTCH3 signaling in vascular remodeling in pulmonary arterial hypertension. Science translational medicine 14, eabl5471.CrossRefGoogle ScholarPubMed
Wang, J et al. (2021) S1P induces proliferation of pulmonary artery smooth muscle cells by promoting YAP-induced Notch3 expression and activation. Journal of Biological Chemistry 296, 100599.CrossRefGoogle ScholarPubMed
Morris, HE et al. (2021) CADASIL-causing Notch3 mutation contributes to the development of pulmonary arterial hypertension in males. Journal of Hypertension 39, p e326.CrossRefGoogle Scholar
Shen, W, Huang, J and Wang, Y (2021) Biological significance of NOTCH signaling strength. Frontiers in Cell and Developmental Biology 9, 652273.CrossRefGoogle ScholarPubMed
Hori, K, Sen, A and Artavanis-Tsakonas, S (2013) Notch signaling at a glance. Journal of Cell Science 126, 21352140.Google ScholarPubMed
Kovall, RA et al. (2017) The canonical Notch signaling pathway: structural and biochemical insights into shape, sugar, and force. Developmental Cell 41, 228241.CrossRefGoogle ScholarPubMed
Ayaz, F and Osborne, BA (2014) Non-canonical notch signaling in cancer and immunity. Frontiers in Oncology 4, 345.CrossRefGoogle ScholarPubMed
Xiu, M et al. (2021) The role of Notch3 signaling in cancer stemness and chemoresistance: molecular mechanisms and targeting strategies. Frontiers in Molecular Biosciences 8, 694141.CrossRefGoogle ScholarPubMed
Hosseini-Alghaderi, S and Baron, M (2020) Notch3 in development, health and disease. Biomolecules 10(3), 485.CrossRefGoogle Scholar
Ceccarelli, S et al. (2019) Notch3 targeting: a novel weapon against ovarian cancer stem cells. Stem Cells International 2019, 6264931.CrossRefGoogle ScholarPubMed
Dang, TP et al. (2003) Constitutive activation of Notch3 inhibits terminal epithelial differentiation in lungs of transgenic mice. Oncogene 22, 19881997.CrossRefGoogle ScholarPubMed
Choy, L et al. (2017) Constitutive NOTCH3 signaling promotes the growth of basal breast cancers. Cancer Research 77, 14391452.CrossRefGoogle ScholarPubMed
Tam, A and Sin, DD (2012) Pathobiologic mechanisms of chronic obstructive pulmonary disease. The Medical Clinics of North America 96, 681698.CrossRefGoogle Scholar
Higham, A et al. (2019) The pathology of small airways disease in COPD: historical aspects and future directions. Respiratory Research 20, 49.CrossRefGoogle ScholarPubMed
Cheng, Z et al. (2015) Cigarette smoke induces the expression of Notch3, not Notch1, protein in lung adenocarcinoma. Oncology Letters 10, 641646.CrossRefGoogle Scholar
Gomi, K et al. (2015) Activation of NOTCH1 or NOTCH3 signaling skews human airway basal cell differentiation toward a secretory pathway. PLoS ONE 10, e0116507.CrossRefGoogle ScholarPubMed
Jespersen, K et al. (2020) Enhanced Notch3 signaling contributes to pulmonary emphysema in a murine model of Marfan syndrome. Scientific Reports 10, 10949.CrossRefGoogle Scholar
Sakai, LY et al. (2016) FBN1: the disease-causing gene for Marfan syndrome and other genetic disorders. Gene 591, 279291.CrossRefGoogle ScholarPubMed
Kainulainen, K et al. (1994) Mutations in the fibrillin gene responsible for dominant ectopia lentis and neonatal Marfan syndrome. Nature Genetics 6, 6469.CrossRefGoogle ScholarPubMed
Neptune, ER et al. (2003) Dysregulation of TGF-beta activation contributes to pathogenesis in Marfan syndrome. Nature Genetics 33, 407411.CrossRefGoogle ScholarPubMed
Uriarte, JJ et al. (2016) Early impairment of lung mechanics in a murine model of Marfan syndrome. PLoS ONE 11, e0152124.CrossRefGoogle Scholar
Singanayagam, A et al. (2022) Airway mucins promote immunopathology in virus-exacerbated chronic obstructive pulmonary disease. Journal of Clinical Investigation 132(8), e120901.CrossRefGoogle ScholarPubMed
Thandra, KC et al. (2021) Epidemiology of lung cancer. Contemporary Oncology 25, 4552.Google ScholarPubMed
Barta, JA, Powell, CA and Wisnivesky, JP (2019) Global epidemiology of lung cancer. Annals of Global Health 85(1), 8.CrossRefGoogle ScholarPubMed
Media, AS et al. (2019) Chronic obstructive pulmonary disease and comorbidities’ influence on mortality in non-small cell lung cancer patients. Acta Oncologica 58, 11021106.CrossRefGoogle ScholarPubMed
Husebo, GR et al. (2019) Risk factors for lung cancer in COPD – results from the Bergen COPD cohort study. Respiratory Medicine 152, 8188.CrossRefGoogle ScholarPubMed
Liao, KM et al. (2021) Impact of chronic obstructive pulmonary disease on the mortality of patients with small cell lung cancer. International Journal of Chronic Obstructive Pulmonary Disease 16, 32553262.CrossRefGoogle ScholarPubMed
Li, C et al. (2013) The roles of Notch3 on the cell proliferation and apoptosis induced by CHIR99021 in NSCLC cell lines: a functional link between Wnt and Notch signaling pathways. PLoS ONE 8, e84659.Google ScholarPubMed
Barse, L and Bocchetta, M (2015) Non-small-cell lung carcinoma: role of the Notch signaling pathway. Lung Cancer 6, 4353.Google ScholarPubMed
Sparaneo, A, Fabrizio, FP and Muscarella, LA (2016) Nrf2 and Notch signaling in lung cancer: near the crossroad. Oxidative Medicine and Cellular Longevity 2016, 7316492.CrossRefGoogle ScholarPubMed
Katoh, M and Katoh, M (2020) Precision medicine for human cancers with Notch signaling dysregulation (review). International Journal of Molecular Medicine 45, 279297.Google Scholar
Dang, TP et al. (2000) Chromosome 19 translocation, overexpression of Notch3, and human lung cancer. Journal of the National Cancer Institute 92, 13551357.CrossRefGoogle ScholarPubMed
Ye, YZ et al. (2013) Notch3 overexpression associates with poor prognosis in human non-small-cell lung cancer. Medical Oncology 30, 595.CrossRefGoogle ScholarPubMed
Li, C et al. (2011) Evidence of the cross talk between Wnt and Notch signaling pathways in non-small-cell lung cancer (NSCLC): Notch3-siRNA weakens the effect of LiCl on the cell cycle of NSCLC cell lines. Journal of Cancer Research and Clinical Oncology 137, 771778.CrossRefGoogle ScholarPubMed
Li, C et al. (2015) Wnt3a increases the metastatic potential of non-small cell lung cancer cells in vitro in part via its upregulation of Notch3. Oncology Reports 33, 12071214.CrossRefGoogle ScholarPubMed
Kudo, M, Ishigatsubo, Y and Aoki, I (2013) Pathology of asthma. Frontiers in Microbiology 4, 263.CrossRefGoogle ScholarPubMed
Al Heialy, S, Ramakrishnan, RK and Hamid, Q (2022) Recent advances in the immunopathogenesis of severe asthma. Journal of Allergy and Clinical Immunology 149, 455465.CrossRefGoogle ScholarPubMed
Carrer, M et al. (2020) Antisense oligonucleotides targeting jagged 1 reduce house dust mite-induced goblet cell metaplasia in the adult murine lung. American Journal of Respiratory Cell and Molecular Biology. 63(1), 46–56.CrossRefGoogle ScholarPubMed
Kang, JH et al. (2009) Gamma-secretase inhibitor reduces allergic pulmonary inflammation by modulating Th1 and Th2 responses. American Journal of Respiratory and Critical Care Medicine 179, 875882.CrossRefGoogle ScholarPubMed
Gu, W et al. (2012) Fringe controls naive CD4(+)T cells differentiation through modulating notch signaling in asthmatic rat models. PLoS ONE 7, e47288.CrossRefGoogle ScholarPubMed
Li, C et al. (2018) Th17/Treg dysregulation in allergic asthmatic children is associated with elevated notch expression. The Journal of Asthma 55, 17.CrossRefGoogle ScholarPubMed
Zhang, W et al. (2015) gamma-secretase inhibitor alleviates acute airway inflammation of allergic asthma in mice by downregulating Th17 cell differentiation. Mediators of Inflammation 2015, 258168.CrossRefGoogle ScholarPubMed
Anastasi, E et al. (2003) Expression of activated Notch3 in transgenic mice enhances generation of T regulatory cells and protects against experimental autoimmune diabetes. Journal of Immunology 171, 45044511.CrossRefGoogle ScholarPubMed
Maekawa, Y et al. (2003) Delta1-Notch3 interactions bias the functional differentiation of activated CD4 + T cells. Immunity 19, 549559.CrossRefGoogle ScholarPubMed
Jeganathan, N, Smith, RA and Sathananthan, M (2021) Mortality trends of idiopathic pulmonary fibrosis in the United States from 2004 through 2017. Chest 159, 228238.CrossRefGoogle ScholarPubMed
Mei, Q et al. (2021) Idiopathic pulmonary fibrosis: an update on pathogenesis. Frontiers in Pharmacology 12, 797292.CrossRefGoogle ScholarPubMed
Martinez, FJ et al. (2017) Idiopathic pulmonary fibrosis. Nature Reviews Disease Primers 3, 17074.CrossRefGoogle ScholarPubMed
Chilosi, M et al. (2002) Abnormal re-epithelialization and lung remodeling in idiopathic pulmonary fibrosis: the role of deltaN-p63. Laboratory Investigation 82, 13351345.CrossRefGoogle ScholarPubMed
Kristensen, JH et al. (2014) The role of extracellular matrix quality in pulmonary fibrosis. Respiration; International Review of Thoracic Diseases 88, 487499.CrossRefGoogle ScholarPubMed
Chambers, RC and Mercer, PF (2015) Mechanisms of alveolar epithelial injury, repair, and fibrosis. Annals of the American Thoracic Society 12(suppl. 1), S16S20.CrossRefGoogle ScholarPubMed
Zhang, Q et al. (2005) Relationship between Notch receptors and hyperoxia-induced lung injury in newborn rats. Journal of Huazhong University of Science and Technology 25, 155158.Google ScholarPubMed
Hu, B et al. (2015) Mesenchymal deficiency of Notch1 attenuates bleomycin-induced pulmonary fibrosis. American Journal of Pathology 185, 30663075.CrossRefGoogle ScholarPubMed
Zhou, Y et al. (2016) Astragalus injection attenuates bleomycin-induced pulmonary fibrosis via down-regulating Jagged1/Notch1 in lungs. Journal of Pharmacy and Pharmacology 68, 389396.CrossRefGoogle ScholarPubMed
Chanda, D et al. (2019) Developmental pathways in the pathogenesis of lung fibrosis. Molecular Aspects of Medicine 65, 5669.CrossRefGoogle ScholarPubMed
Hu, B and Phan, SH (2016) Notch in fibrosis and as a target of anti-fibrotic therapy. Pharmacological Research 108, 5764.CrossRefGoogle ScholarPubMed
Lai, JM et al. (2016) Redox-sensitive MAPK and Notch3 regulate fibroblast differentiation and activation: a dual role of ERK1/2. Oncotarget 7, 4373143745.CrossRefGoogle ScholarPubMed
Gelzinis, TA (2022) Pulmonary hypertension in 2021: part I-definition, classification, pathophysiology, and presentation. Journal of Cardiothoracic and Vascular Anesthesia 36, 15521564.CrossRefGoogle ScholarPubMed
Hassoun, PM (2021) Pulmonary arterial hypertension. New England Journal of Medicine 385, 23612376.CrossRefGoogle ScholarPubMed
Luna-Lopez, R, Ruiz Martin, A and Escribano Subias, P (2022) Pulmonary arterial hypertension. Med Clin (Barc). 158(12), 622–629.CrossRefGoogle ScholarPubMed
Rajagopal, S and Yu, YA (2022) The pathobiology of pulmonary arterial hypertension. Cardiology Clinics 40, 112.CrossRefGoogle ScholarPubMed
Naeije, R, Richter, MJ and Rubin, LJ (2021) The physiological basis of pulmonary arterial hypertension. European Respiratory Journal. 59(6), 2102334.Google Scholar
Tobal, R et al. (2021) Vascular remodeling in pulmonary arterial hypertension: the potential involvement of innate and adaptive immunity. Frontiers in Medicine 8, 806899.CrossRefGoogle ScholarPubMed
Luo, P and Qiu, B (2022) The role of immune cells in pulmonary hypertension: focusing on macrophages. Human Immunology 83, 153163.CrossRefGoogle ScholarPubMed
Lyle, MA, Davis, JP and Brozovich, FV (2017) Regulation of pulmonary vascular smooth muscle contractility in pulmonary arterial hypertension: implications for therapy. Frontiers in Physiology 8, 614.CrossRefGoogle ScholarPubMed
Christou, H and Khalil, RA (2022) Mechanisms of pulmonary vascular dysfunction in pulmonary hypertension and implications for novel therapies. American Journal of Physiology. Heart and Circulatory Physiology 322, H702H724.CrossRefGoogle ScholarPubMed
Ivy, DD et al. (2005) Development of occlusive neointimal lesions in distal pulmonary arteries of endothelin B receptor-deficient rats: a new model of severe pulmonary arterial hypertension. Circulation 111, 29882996.CrossRefGoogle ScholarPubMed
Li, B et al. (2014) Dichloroacetate prevents but not reverses the formation of neointimal lesions in a rat model of severe pulmonary arterial hypertension. Molecular Medicine Reports 10, 21442152.CrossRefGoogle ScholarPubMed
Tsutsumi, T et al. (2019) Nintedanib ameliorates experimental pulmonary arterial hypertension via inhibition of endothelial mesenchymal transition and smooth muscle cell proliferation. PLoS ONE 14, e0214697.CrossRefGoogle ScholarPubMed
Pak, O et al. (2007) The effects of hypoxia on the cells of the pulmonary vasculature. European Respiratory Journal 30, 364372.CrossRefGoogle ScholarPubMed
Rowan, SC et al. (2016) Hypoxic pulmonary hypertension in chronic lung diseases: novel vasoconstrictor pathways. The Lancet. Respiratory Medicine 4, 225236.CrossRefGoogle ScholarPubMed
Lin, L et al. (2010) Targeting specific regions of the Notch3 ligand-binding domain induces apoptosis and inhibits tumor growth in lung cancer. Cancer Research 70, 632638.CrossRefGoogle ScholarPubMed
Konishi, J et al. (2007) Gamma-secretase inhibitor prevents Notch3 activation and reduces proliferation in human lung cancers. Cancer Research 67, 80518057.CrossRefGoogle ScholarPubMed
McCaw, TR et al. (2021) Gamma secretase inhibitors in cancer: a current perspective on clinical performance. The Oncologist 26, e608e621.CrossRefGoogle ScholarPubMed
Dobrowolska Zakaria, JA and Vassar, RJ (2021) A promising new gamma-secretase modulator for Alzheimer's disease. Journal of Experimental Medicine 218(4), e20210077.CrossRefGoogle ScholarPubMed
Cook, N et al. (2018) A phase I trial of the gamma-secretase inhibitor MK-0752 in combination with gemcitabine in patients with pancreatic ductal adenocarcinoma. British Journal of Cancer 118, 793801.CrossRefGoogle ScholarPubMed
Doody, RS et al. (2015) Peripheral and central effects of gamma-secretase inhibition by semagacestat in Alzheimer's disease. Alzheimer's Research & Therapy 7, 36.CrossRefGoogle ScholarPubMed
Penninkilampi, R, Brothers, HM and Eslick, GD (2016) Pharmacological agents targeting gamma-secretase increase risk of cancer and cognitive decline in Alzheimer's disease patients: a systematic review and meta-analysis. Journal of Alzheimer's Disease: JAD 53, 13951404.CrossRefGoogle ScholarPubMed
Hur, JY (2022) gamma-Secretase in Alzheimer's disease. Experimental and Molecular Medicine 54, 433446.CrossRefGoogle ScholarPubMed
Christopoulos, PF et al. (2021) Targeting the Notch signaling pathway in chronic inflammatory diseases. Frontiers in Immunology 12, 668207.CrossRefGoogle ScholarPubMed
Allen, F and Maillard, I (2021) Therapeutic targeting of Notch signaling: from cancer to inflammatory disorders. Frontiers in Cell and Developmental Biology 9, 649205.CrossRefGoogle ScholarPubMed
Li, K et al. (2008) Modulation of Notch signaling by antibodies specific for the extracellular negative regulatory region of NOTCH3. Journal of Biological Chemistry 283, 80468054.CrossRefGoogle ScholarPubMed
Lafkas, D et al. (2015) Therapeutic antibodies reveal Notch control of transdifferentiation in the adult lung. Nature 528, 127131.CrossRefGoogle ScholarPubMed
Canalis, E et al. (2020) Antisense oligonucleotides targeting Notch2 ameliorate the osteopenic phenotype in a mouse model of Hajdu-Cheney syndrome. Journal of Biological Chemistry 295, 39523964.CrossRefGoogle Scholar
Canalis, E et al. (2022) Use of antisense oligonucleotides to target Notch3 in skeletal cells. PLoS ONE 17, e0268225.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. The human respiratory system. (a) Structure of the human respiratory system. (b) Structure of the human pseudostratified mucociliary epithelium. The pseudostratified mucociliary airway epithelium is a continuous single layer of epithelial cells with each cell having direct contact with the basement membrane. The mucociliary epithelium consists of several cell types which can be identified by expression of specific markers. These include, basal cells (KRT5 + , TP63 + ), intermediate (KRT8 + , KRT13 + ), multi-ciliated (FOXJ1 + , DNAI1 + ), goblet secretory (MUC5AC + , MUC5B + ), club secretory (SCGB1A1 + , SCGB3A2 + ), neuroendocrine (CALCA + , ASCL1 + ), pulmonary ionocytes (FOXI1 + , CFTR + ) and brush/tuft (TSLP + , IL-25 + ). The trachea and large airways also harbour submucosal glands which contain additional specialised epithelial cell populations including, serous (LTF + , DCCP1 + ), mucous (MUC5B + , TFF2 + ) and myoepithelial (EPCAM + , ACTA2 + ). Located underneath the basement membrane are a large number of non-epithelial cell populations required to maintain proper structure and function of the respiratory system, including cartilage rings (trachea and large airways only), smooth muscle, fibroblasts, blood vessels, nerves and immune cells (e.g., lymphocytes and dendritic cells). (c) Structure of the human respiratory bronchiole and alveolar epithelium. Terminal respiratory bronchioles are lined predominantly with cuboidal secretory cells (SCGB1A1 + , SCGB3A2 + ) which contain the recently identified progenitor populations termed respiratory airway secretory (RAS) or terminal and respiratory bronchiole secretory cells (TRB-SCs). In contrast, the alveoli consist of alveolar type 1 (AGER + , AQP5 + ) and type 2 (SFTPC + , ABCA3 + ) cells. Type 1 cells are the predominant epithelial cell type in the alveolus and comprise approximately 95% of the gas exchange surface with the underlying vasculature in the lung.

Figure 1

Fig. 2. The NOTCH signalling pathway. (a) Structure of the full-length human NOTCH receptors. The four NOTCH receptors share a common structure consisting of a NOTCH extracellular domain (NECD), transmembrane domain (TD) and a NOTCH intracellular domain (NICD). The NECD contains approximately 29–36 epidermal growth factor (EGF)-like domains, a negative regulatory region (NRR) consisting of three Lin Notch repeats (LNR) and receptor heterodimerisation domains (HD). Following the TD, the NICD contains a RBP-Jκ-association module (RAM) domain, ankyrin (ANK) repeats, a transactivation domain (TAD) and a C-terminal domain rich in proline, glutamic acid, serine and threonine (PEST) domain. The locations of the S1, S2 and S3 cleavage sites are indicated. (b) Schematic of the canonical NOTCH signalling pathway. Canonical NOTCH signalling transduction is relayed via cell-to-cell contact by the direct binding of cell-bound ligand to the NECD of a receptor on a neighbouring cell. Ligand binding results in activation of the NOTCH receptor on the signal-receiving cell via enzymatic cleavage at site 2 (S2) and site 3 (S3) on the NOTCH receptor via the ADAM protease and γ-secretase enzyme, respectively. Following cleavage of the NICD from the receptor and its release into the cytoplasm, the NICD translocates to the nucleus and interacts with transcriptional complexes (RBP-Jκ and MAML1–3) on the promoters of NOTCH target genes, resulting in their transcription.