Extracellular vesicles in Inflammatory Skin Disorders: from Pathophysiology to Treatment

Extracellular vesicles (EVs), naturally secreted by almost all known cell types into extracellular space, can transfer their bioactive cargos of nucleic acids and proteins to recipient cells, mediating cell-cell communication. Thus, they participate in many pathogenic processes including immune regulation, cell proliferation and differentiation, cell death, angiogenesis, among others. Cumulative evidence has shown the important regulatory effects of EVs on the initiation and progression of inflammation, autoimmunity, and cancer. In dermatology, recent studies indicate that EVs play key immunomodulatory roles in inflammatory skin disorders, including psoriasis, atopic dermatitis, lichen planus, bullous pemphigoid, systemic lupus erythematosus, and wound healing. Importantly, EVs can be used as biomarkers of pathophysiological states and/or therapeutic agents, both as carriers of drugs or even as a drug by themselves. In this review, we will summarize current research advances of EVs from different cells and their implications in inflammatory skin disorders, and further discuss their future applications, updated techniques, and challenges in clinical translational medicine.


Introduction
Extracellular vesicles (EVs) are cell membranederived phospholipid bilayer structures that can be produced and released by almost all cell types and range in diameter from 30 to 2000 nm [1]. EVs are found in various biofluids and tissues such as serum, milk, urine, and blister, to name just a few [2]. Currently, EVs are highly heterogeneous and can be classified into three different subtypes based on their size and biogenesis pathway: exosomes (30-150 nm) which are formed by the inward budding of the endosomal membrane during the maturation of multivesicular endosomes, and microvesicles (MVs)/microparticles (100-1500 nm) or apoptotic bodies (500-2000 nm) that are pinched off from the plasma membrane. However, these EV subtypes display overlapping sizes, compositions and densities. Once released into the extracellular space, EVs can be taken up by recipient cells via activation of surface receptors, vesicle internalization (endocytosis), or fusion with target cells to shuttle biological information including various RNAs, lipids and proteins between cells [3]. Thus, EVs regulate multiple biological and pathophysiological processes, including immune responses [4], antibacterial activities [5], cell proliferation and migration [6], and angiogenesis [7,8], among others, suggesting their pathogenic roles in inflammation progression and cancer metastasis.
Multiple methods have been developed to isolate EVs, including density gradient centrifugation, filtration-based methods and affinity-based or precipitation-based methods. Among them, a density gradient combined with ultracentrifugation is the most widely used and highly recommended method, with low yield and high purity [9]. Regarding identification methods, the International Society of Ivyspring International Publisher Extracellular Vesicles has released guidelines that include transmission electron microscopy (TEM), NanoSight particle size analysis, dynamic light scattering, and the identification of protein markers by western blotting or flow cytometry [10]. In some studies, researchers used mass spectrometry to analyze EV proteins and quantify their relative abundances or RNA-sequencing (RNA-seq) to analyze the expression of non-coding RNAs, for example, microRNAs (miRNAs), long non-coding RNAs (lncRNAs), or circular RNA (cirRNAs). EV cargoes reflect their cellular origin and surrounding environmental stimuli.
Recent work from us and others has indicated that EVs play key immunomodulatory roles in the pathogenesis of various inflammatory skin diseases, such as psoriasis [11,12], atopic dermatitis (AD) [13], lichen planus (LP) [14], bullous pemphigoid (BP) [15], systemic lupus erythematosus (SLE) [16], and chronic wound healing [7]. These inflammatory skin disorders pose major problems in dermatology given their complex pathophysiology and refractory nature, which ultimately pose a burden to the health, economic and social systems. As the level of EVs or their cargoes in body fluids may differ between patients and healthy controls, EVs have been used as potential biomarkers of inflammatory skin disorders [17][18][19]. More importantly, EVs are regarded as ideal therapeutic agents in addition to their native bioactivities, and they can be engineered to deliver a variety of proteins, nucleic acids and/or chemicals or drugs. Here, we discuss the current knowledge on the specificities and regulatory functions of EVs (mainly referring to exosomes and MVs) derived from immune and non-immune cells, their roles in the pathogenesis and treatment of inflammatory skin disorders, and the challenges ahead.

Characteristics and functions of EVs from cells associated with cutaneous inflammation
EVs can be secreted by immune or non-immune cells and affect both innate and adaptive immunity, including antigen presentation, cell differentiation and activation, and immune regulation and suppression, among others. In general, EV surface markers and cargo contents as well as the functions of these EVs are closely related to the pro-inflammatory or anti-inflammatory properties of the parent cells, as summarized in Table 1. Here, we mainly discuss the functions of EVs from cells associated with cutaneous inflammation.

Macrophage
Induce autophagy and superoxide anion production in macrophage, thus indirectly promoting the clearance of intracellular mycobacterium tuberculosis. [88] MiRNAs and lncRNAs. Implicate roles in diagnosis and therapeutics in autoimmunity. [85] Nonimmune

Dendritic cell (DC)-derived EVs
DCs are the most efficient antigen-presenting cells that take up, process and present antigens to T cells, which contribute to the initiation and progression of immune responses [20]. Early studies reported that DC-derived EVs expressed high levels of functional major histocompatibility complex (MHC) class I (MHC-I) and class II (MHC-II), MHC-peptide complexes, T cell costimulatory molecules, and tumor antigens [21][22][23]. In addition, it was shown that EVs derived from LPS-induced DCs carried multiple classes of RNAs, including miRNAs, small nucleolar RNAs, Y-RNAs, tRNAs, and small nuclear RNAs [24], which may have roles in balancing T helper 1(Th1)/Th2 responses [25].
DC-EVs have been reported to exert either inhibitory or -stimulatory effects on the immune system, depending on the maturity of the originating cell and the subpopulations of EVs. For instance, EVs from mature DCs carried more MHC-II and costimulatory molecules, which was critical for priming T cell responses and activating the immune system [26][27][28]. In a murine heart transplant model, donor mature DCs released EVs that transferred MHC molecules to recipient conventional DCs, ultimately initiating alloreactive T cell responses and acute rejection [29]. In contrast, in a rat model of liver transplant, EVs derived from immature DCs induced graft tolerance [30]. Moreover, the antigen presenting capacities of EVs from DCs varied among EV subtypes. For instance, compared to MVs derived from mature DCs, small EVs (sEVs) were much more efficient in inducing antigen-specific CD8 + T cells and eliciting antigen-specific immunoglobulin G (IgG) production [31]. Similarly, sEVs derived from immature DCs promoted the secretion of Th1 cytokines, such as interferon-γ (IFN-γ), while larger EVs (lEVs) induced Th2 cytokine secretion [32]. Other functional proteins, such as toll-like receptor 4 (TLR4), could be transferred between DCs through EVs, which increased cellular responsiveness to lipopolysaccharide (LPS)-induced inflammation in recipient cells [33]. In addition, CD301b + perivascular DCs continuously released EVs carrying circulating antigens and allergens to neighboring mast cells, and the latter could vigorously degranulate and trigger anaphylaxis [34]. DC-EVs were also responsible for viral evasion and deposition, as DC-EVs may harbor viral components and transfer infection-associated factors in hepatitis C virus, dengue virus, and human immunodeficiency virus infection [35][36][37].

B cell-derived EVs
B cells are critical modulators of innate and adaptive immune responses as they participate in antigen-specific interactions and antibody production [38]. Similarly, several early studies shown that B cell-EVs expressed a multitude of proteins including MHC-I and MHC-II molecules [39,40], costimulatory and adhesion molecules, C3 fragments [41], CD20, CD45, heat shock proteins, and pyruvate kinase type M2 [40,42], which are crucial for antigen presentation and T cell responses. Interestingly, stimulation of receptors on B cells, such as CD40 and IL-4 receptor, or B cell receptor (BCR) cross-linking, could enhance the secretion of EVs [43,44].
Recently, the functions of B cell-EVs in the tumor microenvironment and inflammation have attracted much attention. EVs derived from CD40/IL-4induced B cells could be loaded with miRNA-155 mimics or inhibitors using the electroporation method and transferred to macrophage cell lines [45], thus reducing the expression of endogenous miRNAs in recipient cells, which suggested that B cell-EVs are an efficient delivery strategy. Klinker et al. reported that MHC-II + FasL + EVs isolated from B cell-derived lymphoblastoid cell lines could induce antigenspecific apoptosis in autologous CD4 + T cells, suggesting that this kind of EVs had immunosuppressive functions [46]. Although B cells and derived autoantibodies are crucial for the progression of cutaneous autoimmune diseases, including BP [29,47] and SLE [48], the roles of B cell-EVs in dermatology are largely unknown and warrant further study.

T cell-derived EVs
T cells are key regulators of the adaptive immune responses involved in inflammatory and autoimmune skin disorders. T cell receptor (TCR) activation and intracellular calcium stimulation could increase EV secretion [49]. It has been shown that T cell-derived EVs contained MHC-I and -II, TCR, CD3, APO2 ligand, adhesion molecules such as CD2 and LFA-1, FasL, and chemokine receptors, among others [49,50]. These bioactive T cell-EVs could be taken up by different cell types, inducing a variety of immunoregulatory effects, such as inhibiting NK cell cytotoxicity [51], regulating DC maturation [52], and enhancing B cell responses and antibody production [4,53].
As T cells are classified into several subsets, their EVs exert distinct effects. It was previously reported that EVs released from CD4 + T cell subsets, including Th1, Th17 and Treg cells, contained different patterns of miRNAs, suggesting distinct functions for T cell subset-derived EVs [54]. Okoye et al. showed that Treg cell-EVs transferred Let-7d to Th1 cells to inhibit their proliferation and IFN-γ secretion, thus contributing to the suppression and prevention of systemic immune diseases [55]. Activated CD8 + T cells not only prevented tumor progression by direct cytotoxicity against tumor cells but also released EVs to induce mesenchymal tumor stromal cell apoptosis [56]. Moreover, another study revealed that T cell-EVs could stimulate human mast cells to degranulate and release several cytokines, such as IL-24, which in turn activated keratinocytes in vitro [57]. Increasing evidence has suggested that EVs also participated in T-B cognate interactions. T cell-EVs or their delivered miRNAs/lipids regulated B cell survival, proliferation, and antibody production [4,53,58], suggesting that T cell-EVs could be engineered to treat B cell overactivation-related diseases.

Macrophage-derived EVs
Macrophages are a highly heterogeneous population that can be activated to differentiate into different phenotypes, including pro-inflammatory M1 or anti-inflammatory M2 macrophages. Macrophages release EVs containing mRNAs that help to identify the phenotype of the parent cells [59]. Using mass spectrometry, the contents of EVs derived from macrophages that were exposed to LPS were identified and included groups of functional proteins, such as plasma membrane-associated proteins, chaperones, metabolic enzymes, cytokines, alarmins, and damage-associated molecular patterns [60][61][62]. It was also shown that macrophage-EVs were enriched in the active accessible pool of cholesterol, which increased the efficiency of cholesterol transfer to high-density lipoprotein, thus lowering the cholesterol level [63]. A recent study reported that Wnt proteins, such as Wnt3a and Wnt7b, were enriched in macrophage-EVs, thus activating the Wnt/β-catenin signaling pathway to enhance hair follicle growth in vivo and in vitro [64].
On the other hand, macrophage-EVs play a pro-inflammatory role in chronic inflammation and metabolic reprogramming. For instance, macrophage-EVs could induce naive monocyte differentiation via transferring miR-223, which regulated host defense and inflammation [65]. EVs released from hemorrhagic shock-activated macrophage promoted reactive oxygen species (ROS) production in neutrophils and their subsequent necroptosis [66]. In addition, macrophage-EVs activated corresponding recipient cells such as fibroblasts [67], hepatocytes [68], or epithelial cells [69], which contributed to the progression of cardiac injuries, liver injuries, or acute lung injuries. Moreover, once EVs derived from DNA damage-induced macrophages were taken up by recipient cells in vivo, the enhanced cellular glucose uptake and metabolic reprogramming in recipient cells triggered pro-inflammatory responses that augmented chronic inflammation [70]. On the other hand, macrophage-EVs are critical for some antiinflammatory reactions. For example, in a diabetic skin wound healing rat model, macrophage-EVs inhibited the secretion of pro-inflammatory mediators, thus inhibiting inflammation and accelerating diabetic wound healing [71]. In addition, macrophage-EVs negatively regulated endothelial cell migration by facilitating the internalization and proteolytic degradation of surface integrin β1 [72]. As macrophages are one of the key regulatory cell populations in the context of chronic inflammation [73], the role of macrophage-EVs in psoriasis, AD, and skin regenerating needs to be further elucidated to advance the field.
As neutrophils are indispensable for controlling bacterial and fungal infections, their EVs contribute to the defense against pathogens in several ways. It has been found that neutrophil-EVs were enriched in antimicrobial proteins, which could inhibit the growth and reproduction of bacteria or fungi [76,86]. Neutrophil-EVs also shuttled arachidonic acid into platelets, and these activated platelets in turn elicited a full neutrophil response, ultimately facilitating neutrophil influx into the lung to eliminate infections [87]. Interestingly, EVs released from Mycobacterium tuberculosis-infected neutrophils could induce autophagy and superoxide anion production in macrophages, thus indirectly promoting the clearance of intracellular Mycobacterium tuberculosis [88].
In addition, neutrophil-EVs can modulate the pro-and/or anti-inflammatory responses of target cells. For instance, neutrophil-EVs enhanced the expression of pro-inflammatory molecules in endothelial cells [89,90]. Neutrophil-EVs containing neutrophil elastase degraded the extracellular matrix, which exacerbated chronic obstructive pulmonary disease [91]. Moreover, we showed that neutrophil-EVs activated adjacent keratinocytes and increased the expression and production of pro-inflammatory mediators, which induced a vicious cycle in severe pustular psoriasis [82]. In addition, neutrophil-EVs exerted anti-inflammatory effects, such as reducing pro-inflammatory mediators to protect the cartilage [92], inhibiting the production of pro-inflammatory cytokines and enhancing anti-inflammatory cytokines in NK cells [93], monocyte-derived DCs [94], or macrophages [95][96][97], which indirectly limited excessive inflammatory responses. Neutrophil-EVs from joint aspirates of gouty arthritis patients had similar anti-inflammatory properties. In response to C5a, neutrophils released phosphatidylserine-positive EVs to suppress the inflammasome activation that was primed by C5a and consequently inhibited IL-1β release and neutrophil influx [98].
Furthermore, neutrophil-EVs also modulate endothelial permeability and vascular remodeling in a cargo-dependent manner. Neutrophil-EVs were able to disrupt junctional integrity and increase permeability due to the activities of S100A8, S100A9, myeloperoxidase (MPO), and cathepsin G, among others [81,99] [100][101][102]. In contrast, neutrophil-EVs transferring barrier-protecting proteins, such as annexin 1, maintained junctional integrity and decreased permeability [103,104]. Thus, it is worth further exploring the regulatory role of neutrophil-EVs in inflammatory skin diseases that display vascular remodeling in skin lesions.

Mesenchymal stem cell-derived EVs
Mesenchymal stem/stromal cells (MSCs) are self-renewing, multipotent stromal cells that can differentiate into a variety of cell types. MSCs mainly exert immunomodulatory effects associated with tissue homeostasis and regeneration. MSC-derived EVs are reported to have multiple biological functions, including anti-inflammation, tissue repair, immunosuppression, and neuroprotection [105]. Thus, recent studies have focused on exploiting MSCs-EVs as a possible noncellular therapy, which will be discussed in Section 4 of this review. RNA-seq studies showed that MSC-EVs were enriched for distinct classes of RNAs [106][107][108], and the proteomics profiling of MSC-EVs identified functional proteins involved in cell proliferation and apoptosis, inflammation, extracellular matrix remodeling, and angiogenesis [109][110][111][112].
In general, MSC-EVs mainly play protective roles in inflammation. For instance, in tubular or renal injury, MSC-EVs regulated proliferative or antiapoptotic pathways in tubular epithelial cells [113,114], shuttled several pro-angiogenic transcription factors [115], or suppressed CX3CL1 expression and reduced the subsequent infiltration of macrophages in the damaged kidney [116]. Recent in vivo studies further indicated that MSC-EVs promoted the recovery of kidney function in animal models of ischemia-reperfusion-induced acute kidney injury, which could be considered as a future potential therapy [117]. Moreover, some studies have reported that MSC-EVs could be used for the treatment of liver diseases, as MSC-EVs suppressed the epithelial-tomesenchymal transition [118], increased hepatocyte regeneration [119], and decreased the proliferation of hepatic stellate cells [120]. They also reduced the level of serum alanine aminotransferase and proinflammatory cytokines in liver injury mice, suggesting that MSC-EVs have anti-inflammatory effects in liver injury [121]. Human umbilical cord MSC-EVs carrying circular RNAs could inhibit ischemia-induced pyroptosis and the release of downstream IL-1β and IL-18, which helped repair ischemic muscle injury [122].
In dermatology, adipose tissue-derived MSC-EVs attenuated pathological symptoms in an AD mouse model, reducing clinical scores levels of IgE and eosinophils in the blood, the infiltration of immune cells in skin lesions, and the mRNA expression of various inflammatory cytokines [123], which indicated that MSC-EVs could be a novel and promising therapeutic strategy for AD treatment.

Keratinocyte-derived EVs
Keratinocytes, the main components of the epidermis, can sense pathogens and mediate immune responses. Dysregulation of keratinocytes and their crosstalk with other immune cells gives rise to the initiation and propagation of inflammatory skin diseases in susceptible individuals [124]. Similar to EVs derived from other cells, keratinocyte-EVs also vary in composition and abundance of contents depending on the parent cell status and stimulus. For example, IL-17A-treated keratinocytes released EVs containing β-defensin 2 and chemoattractants such as CXCL1, CXCL3, CXCL5, and CXCL6 [125]. In addition, Staphylococcus aureus (S. aureus) enterotoxin B-loaded HaCaT cells (a keratinocyte cell line) released EVs containing MHC molecules, which promoted CD4 + and CD8 + T cell proliferation in vitro [126]. Keratinocyte-EVs were also reported to carry a set of miRNAs that helped discriminate between EV subpopulations [127].
Keratinocytes-EVs are actively involved in cellular cross-talk, thus regulating various functions associated with skin homeostasis, including wound healing, proliferation, and pigment production. For example, keratinocyte-EVs carried cathepsin B, transforming growth factor binding protein, and matrix metalloproteinase-1, which stimulated fibroblasts to facilitate extracellular matrix remodeling and subsequent keratinocyte migration during wound healing [128,129]. In skin pigmentation, EVs from ultraviolet B-irradiated keratinocytes significantly increased both the expression and activity of melanosomal proteins in melanocytes [130], partially explaining how the cell crosstalk regulated pigmentation. In addition, EVs derived from keratinocyte induced by IFN-γ could be internalized by bone marrow-derived cells, and the latter cells differentiated into a mature phenotype with enhanced CD40 expression and increased IL-6, IL-10, and IL-12 production [131]. Given that keratinocytes play vital roles in host defense and immune responses in skin lesions, it is hypothesized that their EVs may act as regulators in the complicated immune disorders of inflammatory skin diseases.

Fibroblast-derived EVs
Fibroblasts can synthesize the major components of the extracellular matrix in connective tissue, thus maintaining the structural integrity of most tissues. Increasing evidence indicated that fibroblasts and their derived EVs exhibited functional specializations according to their source organ and spatial location [132]. For instance, cardiac fibroblasts-EVs could transfer miR-21-3p to cardiomyocytes and induce cardiomyocyte hypertrophy [133]. Fibroblast-EVs from patients with eosinophilic asthma promoted epithelial cell proliferation, thus contributing to airway remodeling in severe asthma [134]. Fibroblast-EVs from scleroderma patients exhibited dysregulated collagen-related miRNA levels and further upregulated the expression of type I collagen in fibroblasts to facilitate wound healing [135]. Similarly, fibroblast-EVs could shuttle miR-23a-3p to accelerate scratch closure of epidermal keratinocytes in vitro [136]. Moreover, fibroblast-EVs significantly inhibited the production of ROS and cell death in fibroblasts induced by ultraviolet B radiation, thus playing a critical role in skin homeostasis during photoaging [137].

Adipocyte-derived EVs
Nowadays, the adipose tissue has been recognized as an endocrine organ that secretes pleiotropic bioactive molecules that modulate metabolism in distant organs and immune cell functions [138]. Adipogenesis was thought to affect EV structure, molecular composition, and function, as EV production was higher in cells before adipogenesis [139]. Interestingly, mouse perigonadal adipose tissue in leptin-deficient obese mice released more EVs than that of lean mice [140], and the cargoes and regulatory functions of these EVs were also different [141,142]. Protein profiling has revealed that EVs released by adipose tissue carried adipokines such as adiponectin, IL-6, monocyte chemoattractant protein-1, and resistin [143]. In addition, these EVs also harbored enzymes including fatty acid synthase, acetyl-CoA carboxylase, glucose-6-phosphate dehydrogenase, immunomodulatory proteins and cytokines, as well as various mRNAs [144,145]. Further, two subpopulations of adipocyte-EVs, small EVs and large EVs, were identified and shown to exhibit specific protein signatures [146]. Notably, the functions of EVs released from adipocytes in different differentiation states were varied. For instance, EVs from immature adipocytes were shown to induce telogen-to-anagen transitions in hair follicles, whereas those from mature adipocytes inhibited hair follicle progression [147]. Therefore, it can be hypothesized that under different circumstances, adipocytes secrete EVs with distinct regulatory functions, contributing to diverse immune responses.
Adipocyte-EVs, now regarded as a new adipokine, exert regulatory functions in metabolic processes and insulin resistance [148]. It was reported that circulating EVs were significantly increased in obese mice and humans compared to lean controls, and could be biomarkers of metabolic stress [149]. Besides, EVs derived from the adipocytes of obese mice increased appetite and weight when administered to lean mice, whereas EVs from the adipocytes of lean mice decreased the weights of obese mice [150], indicating their regulatory role in obesity and metabolic diseases. Another study reported that obese adipocytes released high levels of exosomal miR-27a, which repressed PPAR-γ and induced insulin resistance in skeletal muscle [151].
In addition, adipocyte-EVs play pathogenic roles in immune responses via exerting effects on various cells. Adipocyte-EVs from obese mice induced M1 macrophage polarization to exacerbate intestinal inflammation [152]. In addition, EVs from diabetic adipocytes or high glucose/high lipid-challenged non-diabetic adipocytes were enriched in miR-130b-3p, which aggravated myocardial ischemia/ reperfusion injury in the diabetic heart [153]. Similar findings have been reported in perivascular adipose tissues, where adipocyte-EVs from obese mice evoked inflammatory responses and vascular remodeling [154]. Moreover, TNF-α/TNF-α + hypoxia-induced adipocyte-EVs enhanced neutrophil adhesion by increasing vascular cell adhesion molecule expression on one vascular cell line [155]. Considering the critical roles of adipocytes in skin repair and inflammatory states, future studies of these EVs will have far-reaching implications.

Figure 1. Extracellular vesicles (EVs) in the cell-cell crosstalk of psoriasis.
Keratinocyte-EVs induced by psoriatic cytokines such as IL-17A can be taken up by neighboring keratinocytes to upregulate mRNA expression of β2 defensin and chemokines, by neutrophils to induce NETosis and the production of IL-6, IL-8, and TNF-α in neutrophils, or by CD4 + T cells to facilitate Th1/Th17 polarization. In turn, neutrophil-EVs also induce keratinocytes to produce a variety of chemokines to attract more immune cells. In addition, IFN-α promotes mast cells to secrete EVs, which induces the generation of neolipid antigens and subsequent recognition by lipid-specific CD1a-reactive T cells. Neu, neutrophils; NETs, neutrophil extracellular traps.

EV involvement in the pathophysiology of inflammatory skin disorders
Chronic inflammatory skin diseases, including psoriasis, AD, LP, and SLE, among others, are refractory with long-lasting courses. Though biological drugs such as anti-TNF, anti-IL-17, and anti-IL-12/23 agents show treatment-associated benefits, the complex pathogenesis is insufficiently understood, which warrants further exploration. Here, we will mainly describe how EVs participate in complicated pathophysiological processes involved in inflammatory skin disorders.

Psoriasis
Psoriasis is the most common chronic inflammatory skin disease and is characterized by abnormal proliferation and differentiation of keratinocytes and massive infiltration of immune cells [156]. A number of studies have shown that endothelial cell-and platelet-derived EVs were increased in patients with psoriasis [157][158][159][160][161], were positively correlated with the psoriasis area and severity index score [157], and were decreased by anti-TNF-αbut not anti-IL-12/23 treatment [162]. Besides, psoriasis-related cytokines modulated the production of EVs, as IL-17A induced HaCaT cells to produce EVs carrying the mRNAs of several chemokines and β-defensin 2 [125]. Recent studies attempted to analyze the miRNA profiles in plasmaderived EVs to illustrate their potential as future psoriasis biomarkers [17,163].
Studies on the functions of EVs in psoriasis have gradually developed in recent years (Figure 1). As one early study revealed, IFN-α induced mast cells to release EVs that were capable of transferring cytoplasmic PLA2 activity to neighboring CD1aexpressing cells, which further led to the generation of neolipid antigens and subsequent recognition by CD1a-reactive T cells [11], which established EVs as critical mediators in psoriasis. Our recent study demonstrated that EVs isolated from psoriatic cytokine-induced keratinocytes could be endocytosed by neutrophils and induced the latter to produce NETs and pro-inflammatory cytokines, thus exacerbating psoriatic inflammation [12]. Interestingly, neutrophils from patients with generalized pustular psoriasis secreted more EVs than those from controls, and further triggered keratinocytes to produce high levels of inflammatory molecules, such as IL-1β, IL-36G, IL-18 and TNF-α [82]. These results suggest that EVs are critical mediators of keratinocyte-neutrophil crosstalk in the pathogenesis of psoriasis. Moreover, our latest study revealed that EVs derived from psoriatic keratinocytes transferred miR-381-3p to CD4 + T cells, inducing Th1/Th17 polarization and promoting psoriasis development [164]. Interestingly, it was reported that EVs from two similar diseases, rheumatoid arthritis (RA) and psoriatic arthritis (PsA), showed divergent effects, as RA-derived or healthy control-derived EVs profoundly inhibited osteoclast differentiation while PsA-derived EVs had a stimulatory effect [165]. Therefore, by comprehensively studying the biological functions of EVs, we will gain important insights regarding their roles in the immune network of psoriasis, or other associated syndromes.

Atopic dermatitis
AD is another common inflammatory skin disease, characterized by typical type 2 skin inflammation with a defective barrier [166,167]. As AD patients are susceptible to S. aureus infection, which in turn aggravates AD inflammationassociated, several studies have explored the role of S. aureus-derived EVs in AD. S. aureus-EVs could exacerbate AD inflammation by delivering bacterial effector molecules to host cells, thus aggravating the inflammatory responses (Figure 2). For instance, it was reported that S. aureus-EVs efficiently increased the production of pro-inflammatory mediators such as IL-6, thymic stromal lymphopoietin, and macrophage inflammatory protein-1α in dermal fibroblasts [168], triggered HaCaT cells to overexpress proinflammatory cytokines including IL-1β, IL-6, IL-8, and MIP-1α [169], and induced endothelial cell activation and monocyte recruitment [13]. In addition, it was shown that α-hemolysin transported in S. aureus-EVs induced keratinocyte necrosis, exacerbating both skin barrier disruption and AD-like skin inflammation [170]. Thus, S. aureus-EVs may be regarded as one of the therapeutic targets for the management of AD aggravation. Notably, EVs derived from thymol-treated S. aureus or Lactobacillus plantarum alleviated the AD-like skin lesions including epidermal thickening and IL-4 level [171,172], indicating their potential to treat AD.

Lichen planus
LP is the third most common inflammatory skin disease, characterized by epidermal keratinocyte death and dense infiltration of T cells in the dermis [173]. We previously provided evidence of the role of IFN-γ in the cell-mediated cytotoxicity of keratinocytes in LP [174]. Recently, several studies explored the function of EVs in LP. For instance, one study profiled salivary EVs from patients with oral LP and identified miR-4484, miR-1246, and miR-1290 as enriched miRNAs in LP, making these molecules potential biomarkers for oral LP [19]. In addition, it was shown that circulating EVs in erosive oral LP patients enhanced T cell proliferation and attenuated T cell apoptosis [14]. Thus, further studies are warranted to profile and determine the pathogenic roles of EVs derived from skin lesions or circulation of LP patients.

Bullous pemphigoid
BP is a severe autoimmune inflammatory disorder and clinically manifests as subepidermal blisters and erosions of the skin and/or mucous membranes [175]. Blister fluid contains infiltrated immune cells, cytokines, and chemokines, as well as EVs, all of which are capable of exerting biological functions and promoting inflammatory responses. We showed that EVs isolated from the blister fluid of BP patients could be internalized by human keratinocytes, which led to the production of critical inflammatory cytokines and chemokines, enhancing neutrophil trafficking to skin lesions and triggering local autoinflammatory responses [15]. Neutrophils were reported to be critical for blister formation and exacerbated inflammation in BP [176,177]. We also employed mass spectrometry to elucidate the proteome of blister fluid-derived EVs for the first time, showing that they contained a variety of proteins implicated in autoimmunity and inflammatory responses [15]. However, the contributions of neutrophil-, T cell-, B cell-, and other monocyte-EVs to the initiation and progression of BP are largely unknown.

Systemic lupus erythematosus
SLE is a chronic, refractory, and systemic autoimmune disease characterized by circulating autoantibodies and the formation of immune complexes. It harms multiple organs and presents a variety of clinical manifestations [178]. To date, the contents and functions of EVs carrying autoantigens, cytokines, surface receptors, and non-coding RNAs have been studied in SLE. As early studies reported, the total number of EVs and IgG-positive EVs were increased in the plasma of SLE patients [18,179], and their high levels were positively correlated with anti-DNA levels, suggesting that these EVs could represent an important source of immune complexes in SLE [180]. Nielsen et al. showed that the level of annexin V non-binding cell-derived EVs was positively correlated with disease severity and some systemic indicators [181]. They further found that the levels of IgG, IgM, and C1q were elevated in EVs from SLE patients compared with those from healthy controls [182]. Nevertheless, it was not clearly demonstrated whether IgG in EVs had autoantibody activity. It was also reported that CD31 + /annexin V + /CD42b -MVs [182] or CD41 + EVs harboring IgG [183] were higher in SLE patients than in controls. Using high-sensitivity nano-liquid chromatography tandem mass spectrometry, 248 proteins were found to be significantly upregulated in the circulating EVs isolated from SLE patients relative to those of the controls [184]. In addition, another recent study measured EVs by flow cytometry to identify small (0.2-0.7 μm) and large (0.7-3.0 μm) EVs, and showed that patients with active lupus nephritis had increased levels of large EVs containing mitochondria (mitoEVs) and IgG-positive mitoEVs, indicating that distinct EV subpopulations can have different functions in SLE [185]. Further, urinary EVs of SLE patients were also identified and enriched in miRNAs, with miR-146a being the most prominent [186].
Moreover, it was shown that these increased EVs in the plasma of active SLE patients induced ROS production and degranulation in neutrophils [187], activated pDCs to secrete IFN-α via TLR7 [188], or contributed to MSC senescence in SLE [189]. The elevated EVs and their immune complexes in SLE patients also promoted secondary leukocyte infiltration by regulating vascular remodeling and chemokine secretion [16]. Moreover, EVs derived from platelets mostly harbored IgG and overexpressed CD69 and CD64, and promoted pro-inflammatory responses in monocytes, thus exacerbating SLE-associated inflammation [190].
Thus, it is worth noting that EVs play a crucial role in initiating and aggregating autoimmune reactions in SLE.

Chronic wound healing
Wound healing is a complex and dynamic process that includes hemostasis, inflammation, angiogenesis, re-epithelialization and remodeling [191]. However, the disturbances in this process, common in diabetes and aging individuals, lead to chronic wounds, a dilemma in dermatology [192,193]. A variety of cell types with distinct roles are involved in the different phases of chronic wound healing, including neutrophils [194], macrophages [195], mast cells [196], DCs [197], T cells [198], fibroblasts [199], and others [192]. Therefore, EVs, cytokines, growth factors, and chemokines derived from multiple sources can actively regulate complex cellular signaling networks.
Numerous studies have focused on pathogenic factors and new techniques to promote wound healing. According to recent studies, EVs can contribute to multiple stages of wound healing cascades such as cell proliferation and differentiation [200], coagulation [201], angiogenesis [202], and extracellular matrix remodeling [203]. For instance, EVs isolated from platelet-rich plasma could effectively induce the proliferation and migration of endothelial cells and fibroblasts to improve angiogenesis and re-epithelialization in chronic wounds, therefore showing efficacy in chronic wounds in a diabetic rat model [204]. EVs released from corneal epithelial cells were enriched in provisional matrix proteins, fibronectin, and thrombospondin-1, promoting the differentiation of myofibroblasts in the development of corneal scars [200]. Similarly, EVs carrying miR-21, which were mainly derived from resident keratinocytes, were elevated in the wound fluid of healing chronic wound patients, and able to convert M1-polarized human macrophages to fibroblast-like cells; however, the conversion was strikingly impaired in a mouse model of experimental diabetes, and could be rescued by nanoparticles delivering miR-21 to macrophages [205]. However, advanced glycation end products induced human umbilical vein endothelial cells to secrete EVs enriched in miR-106b-5p, which triggered fibroblast autophagy, thus decreasing collagen synthesis and delaying cutaneous wound healing [206]. EVs derived from normal and diabetic human corneolimbal keratocytes exhibited distinct contents, and accelerated or delayed the proliferation of limbal epithelial cells in wound healing [207]. Therefore, we hypothesize that EVs derived from various sources contribute to the local immune responses in chronic wound healing.

EVs as biomarkers in inflammatory skin disorders
EVs are mainly regarded as diagnostic and prognostic biomarkers in cancer but are still largely unexplored in skin inflammatory diseases. Recently, increasing evidence has indicated their potential role as noninvasive biomarkers for predicting the onset, relapse or reaction to drugs in the field of inflammatory skin disorders.
Several studies on psoriasis, SLE, AD, and LP [19] aimed to explore the role of EVs as biomarkers (Figure 3). For instance, the level of IL-17A + EVs in Figure 3. Extracellular vesicles (EVs) are potential biomarkers in inflammatory skin disorders. EVs derived from various origins have the potential to serve as biomarkers in several inflammatory dermatoses, including psoriasis, LP, and SLE. In psoriasis, the level of IL-17A + EVs in circulation was significantly higher in patients with moderate-to-severe psoriasis than in those with mild psoriasis. MiR-199a-3p was the most up-regulated in serum EVs from psoriasis patients, implicating its diagnostic role in future study. Let-7b-5p and miR-30e-5p in serum EVs were significantly lower in patients with PsA, suggesting that circulating EV miRNAs might serve as biomarkers for PsA. In SLE, the increase in endothelial EVs or circulating EVs carrying several immune molecules was positively correlated with disease activity. And urinary EVs of SLE patients were also identified and enriched in miRNAs, with miR-146a being the most prominent. Urinary EVs containing let-7a and miR-21 were significantly down-regulated in lupus nephritis patients, and elevated after the complete course of effective treatment. In LP, salivary EVs of patients from oral LP were enriched in miR-4484, miR-1246, and miR-1290, making them potential biomarkers for oral LP. circulation was significantly higher in patients with moderate-to-severe psoriasis than in those with mild psoriasis, suggesting that the components of EVs could be indicators of distinct disease stages [161]. Another study further compared the plasma-derived EV miRNAs from cutaneous-only psoriasis patients (n=15) with those of PsA patients (n=14), showing that let-7b-5p and miR-30e-5p in plasma-derived EVs were significantly lower in PsA patients, which suggested that circulating EV miRNAs might serve as biomarkers for PsA [163]. A recent study profiled the miRNAs of EVs from psoriasis patients (n=52) and healthy controls (n=26) and revealed that 26 miRNAs were upregulated and 24 were downregulated, with miR-199a-3p the most differentially expressed in psoriasis [17]. These results highlight the potential of EVs as diagnostic markers for psoriasis patients, however, larger samples and the pathogenic roles of EVs should be considered in the future. In SLE, several studies have suggested that the levels of circulating EVs were correlated with disease activity and clinical features, indicating that EVs could be reliable biomarkers of SLE activity [18,181,184]. For instance, it was shown that the increase in endothelial EVs was positively correlated with disease activity, glomerulonephritis, and vascular dysfunction [181], and was reduced by immunosuppressive therapy with decreasing cardiovascular risk [208]. Urinary EVs containing let-7a and miR-21 were significantly down-regulated in lupus nephritis patients and elevated after complete course of effective treatment, suggesting that urinary EV-associated miRNAs could be used as liquid biopsies to estimate the clinical stage of lupus nephritis patients [209]. In addition, as one recent study preliminarily explored, serum microbial EVs showed potential as novel biomarkers for AD diagnosis [210].
Further studies of the novel ways that EVs can reflect disease pathogenesis or clinical stages, predict relapse or prognosis, indicate responses to therapies, or guide therapy beyond current biomarkers are needed.

EVs as therapeutic agents in inflammatory skin disorders
Currently, EVs are being explored as nanotherapeutic agents for immune therapy, regenerative medicine, and drug delivery. In dermatology, studies on EVs are just beginning to show promising prospects in inflammatory skin disorders. As mentioned above, adipose tissuederived MSC-EVs showed promising results as a cell-free therapeutic modality for AD treatment [123]. Several other investigations have demonstrated the potential uses of MSC-and APC-derived EVs as cell-free agents to treat autoimmune diseases. It was reported that the transplantation of MSCs would rescue bone marrow MSC function in a lupus knockout mouse model via transferring EVs-derived Fas to recipient cells [211]. Another study showed that MSC-EVs were successfully used to treat a patient with refractory graft-versus-host disease and showed sustained alleviation of cutaneous and mucosal manifestations after 4 months [212].
Moreover, several studies have shown that EVs can be used as therapeutic agents in wound healing. EVs derived from umbilical cord blood were shown to be enriched in miR-21-3p, and promoted the proliferation and migration of fibroblasts and enhanced the angiogenic activities of endothelial cells, thus accelerating re-epithelialization and cutaneous wound healing [213]. Keratinocyte-EVs could also modulate fibroblast function and angiogenesis by transferring miR-21 to facilitate skin wound healing [7]. EVs from oral mucosa epithelial cells of human healthy donors showed pro-regenerative effects on skin wound healing [214], and EVs from human urine-derived stem cells could promote angiogenesis and wound healing in diabetic mice [215]. Interestingly, Synechococcus elongatus-EVs were capable of augmenting endothelial angiogenesis and stimulating new blood vessel formation, indicating that Synechococcus elongatus-EVs maybe a promising strategy for wound healing [202]. It was shown that MSCs-EVs maintained or accelerated rapid wound healing by activating fibroblasts [203], epithelial cells [216], or gingiva wound healing [217], which provided a potential therapeutic approach in this field.
Nowadays, the combination of EVs and biomaterials to enhance the wound healing process represents a novel approach for chronic wound therapy [218]. One study developed an injectable antibacterial hydrogel with stimuli-responsive adipose-derived MSC-EVs, which could efficiently accelerate chronic wound healing and skin regeneration with coordinated actions [219]. More recently, a study reported that a light-activated hydrogel containing small EVs isolated from human mononuclear cells promoted wound healing, a process that was partially orchestrated by EV-miRNAs [220]. Additionally, allogenic EVs isolated from adipose tissue-derived stromal cells were engineered into a thermoresponsive gel, which resulted in a statistically significant improvement in fistula healing [221]. To date, several phase-I or phase-II clinical trials have been conducted to study whether EVs can be used in humans without life-threatening complications [222,223]. However, only one clinical trial was established to study the use of EVs in the treatment of skin diseases. AGLE-102 is an allogeneic EV derived from normal donor MSCs. One phase 1/2A, multi-center, randomized study aimed to assess the safety and efficacy of AGLE-102 in the treatment of lesions in epidermolysis bullosa patients (NCT04173650).
Importantly, EVs, especially exosomes, have great potential as drug delivery vehicles. They are suitable for delivering therapeutic agents due to their natural properties, including material transportation, stability in circulation, relatively long half-lives, and excellent biocompatibility [224]. For instance, EVbased drug formulations offer a powerful and novel delivery platform for anti-cancer and -inflammation therapy [225][226][227]. For example, since the transcription factor nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) plays a pivotal role in modulating the inflammatory cascades in a variety of inflammatory diseases, including septic shock and psoriasis, an optogenetically engineered EV system was employed to load a large amount of superrepressor IκB into EVs. These engineered EVs were taken up by recipient cells and then attenuated systemic inflammation in septic model mice [228]. Though several techniques are in use for drug loading and targeted delivery, a standard effective method is still lacking. Existing methodologies include the incubation of drugs with EVs, electroporation or saponification to induce the formation of small pores within the membranes, freeze-thaw methods that can cause the degradation of many EV proteins, and the transfection of nucleic acids into the secreting cells, among others [229]. Any method can be selected depending on the study demand and its advantages. Therefore, to exploit the therapeutic potential of EVs, innovative approaches and full considerations are required.
Based on the availability, cost of production and safety, plants, fruits, and even milk can be used as sources from which to isolate EVs for clinical use [230]. For instance, anti-tumor drugs such as doxorubicin and curcumin were loaded on grapefruit-EVs decorated with targeting modifications, and showed anti-inflammatory effects in tumor-bearing mice [231]. Milk-EVs were reported to survive harsh and degrading conditions in the gut and then taken up by various cell types. Thus, several studies isolated EVs from milk and attempted to load them with various drugs with high yield and safety [232][233][234]. Thus, these innovations and updated techniques can be considered in the future study of EV utility in inflammatory skin diseases.
In dermatology, the combination of EVs and biomaterials in regenerative medicine warrants in-depth study in mouse models and clinical trials, for instance, in wound healing and hair regeneration. The topical use of this kind of EV will also show promising prospects in treating inflammatory skin diseases. With improved understanding of EV functions and the development of related bioengineering strategies, it is possible to develop therapeutic applications such as EVs enriched in the cargo of interest, with enhanced targeting properties or decorated with physiological or synthetic ligands to target specific receptors that are overexpressed in different autoimmune diseases.

Challenges and Future Directions
Currently, several major challenges limit the broader translational use of EVs. As the EV classifications are continuously evolving, one problem is the lack of unique markers for the heterogeneous subclasses of EVs, which overlap in sizes, biophysical properties, and contents [235]. Therefore, the ISEV suggested the use of physical characteristics (such as small EVs), biological composition (some protein positive EVs), or descriptions of conditions (such as hypoxic EVs) to name the EV subtypes [236]. Since the isolation methods and approaches for EV analysis are evolving [237], standard methods need further validation.
One proposed solution is to comprehensively study the biogenesis and cargo content of all EVs from multiple cell types [238]. Using asymmetric flow field-flow fractionation, one group identified two exosome subpopulations, large exosomes (90-120 nm) and small exosomes (60-80 nm), and discovered an abundant population of nonmembranous nanoparticles termed "exomeres" (~35 nm). Each subpopulation showed unique protein and nucleic acid profiles, as well as biophysical properties, suggesting a distinct biological function for each subpopulation [239]. Besides, fourier-transform infrared spectroscopy provided collective fingerprints of EV subpopulations including large (~600 nm), medium (~200 nm), and small (~60 nm) EVs [240]. Moreover, diverse subpopulations of plasma EVs were identified using high-sensitivity fluorescenceactivated vesicle sorting and showed that erythrocyteand platelet-derived EVs carried distinct repertoires of nucleic acids that were similar to those of their original sources [241]. Therefore, as increasing evidence has shown that EV subclasses carry different cargoes, it is necessary to develop standardized and effective methods to identify and isolate the different EV subpopulations.
Current EV isolation methods yield many nonvesicular proteins and contaminated EVs, which limit the profiling of nucleic acids or proteins in EVs. Thus, several techniques were developed to improve our understanding of EV contents. A recent study used a trypsin-digested proteomics approach to classify trypsin-sensitive and trypsin-resistant vesicular proteins, and to systematically study the actualvesicular proteins, which helped to identify reliable functional proteins, and revealed their pathophysiological roles, an important aspect in the use of EVs as liquid biopsies [242]. In addition, new techniques such as exosome-templated nanoplasmonics [243] and nanopatterned microchips [244] were recently developed to accurately and sensitively monitor the molecular profiles of EVs, which would facilitate the development of liquid biopsies.
Further, how to identify and clearly observe EVs has been a major obstacle in understanding EVs and their utility. Notably, new technologies have flourished in recent years. For instance, one study used a non-pH-sensitive red fluorescent tag to visualize the lifecycle and biogenesis of EVs, including multivesicular body (MVB) trafficking, MVB fusion, EV uptake, and endosome acidification [245]. To quantify EV uptake at the single-cell level, another study developed an engineering approach that combined mass cytometry with highly multivariate cellular phenotyping. This innovation could help to unravel the in vivo fate of EVs taken up by recipient cells, elucidating the mechanism of action of EVs in vivo [246]. The updated technologies tracking EVs will improve our mechanistic understanding of the biodistribution of EVs.
Nowadays, efforts to increase the production of EVs by cells for future therapeutic applications are ongoing. Conventional isolation methods such as ultracentrifugation require multiple steps that cause significant loss and damages to EVs. To overcome this limitation, researchers have developed several methods to increase the yield of EVs or to engineer EVs. One strategy is to increase EV biogenesis in the donor cell by overexpressing regulatory proteins involved in EV biogenesis [247] or increasing MVB docking at the plasma membrane [248]. Besides, physical conditions including radiation, hypoxia, and low pH were reported to upregulate EV production. For instance, nitrogen cavitation was used to instantly disrupt neutrophil-like HL60 cells leading to a 16-fold increase in the formation of nanosized membrane vesicles, which were then loaded with an antiinflammation drug to treat acute lung inflammation/ injury and sepsis induced by LPS [249]. Ultrasonication of MSCs for 1 min also improved the EV yield, which exhibited ∼20-fold higher and ∼100-fold faster production than the natural secretion [250]. A recent study described a detailed method to fabricate an origami-paper-based device that integrated the ion concentration polarization technique for effective enrichment and isolation of EVs in a simple manner [251]. Further, engineered EVs showed promising roles in this field. One group developed a system to engineer EVs to sustainably release TGF-β1, IL-2, and rapamycin to induce Treg differentiation from naïve T cells [252]. However, more studies should be conducted to ensure that the engineered EVs exhibit stable bioactivities and efficacies, stable packing of biological materials, and little cytotoxicity.

Conclusions
In recent years, we have witnessed a boom in EV studies in the context of nearly all diseases, such as in the dysregulation and treatment of cancers, inflammation, and autoimmune diseases. Therefore, we reviewed the regulatory functions of immune and non-immune cell-derived EVs, and their roles in inflammatory skin disorders, as triggers of immune responses, potential biomarkers, or therapeutic agents. However, the studies are just beginning in dermatology, and the precise contents of most EV preparations or their multiple functions remain to be deciphered. Likewise, new strategies and more comprehensive studies are needed to identify EV subpopulations with high accuracy and selectivity, and to address the emerging challenges. We are optimistic that continuing studies on EVs will allow future application of EVs in the detection and treatment of various inflammatory skin diseases.