- 1Sorbonne Université, UPMC Univ Paris 06, INSERM, CNRS, Institut de la Vision, Paris, France
- 2Department of Ophthalmology III, Quinze-Vingts National Ophthalmology Hospital, Paris, France
- 3Quinze-Vingts National Ophthalmology Hospital, DHU Sight Restore, INSERM-DGOS CIC 1423, Paris, France
- 4Santen SAS, Evry, France
- 5iGE3 Genomics Platform University of Geneva, Geneva, Switzerland
- 6Department of Ophthalmology, Ambroise Paré Hospital, APHP, University of Versailles Saint-Quentin en Yvelines, Boulogne-Billancourt, France
- 7Sorbonne Paris Cité Université Paris Descartes, Faculté de Pharmacie de Paris, Paris, France
Purpose: In several multicenter clinical trials, HLA-DR was found to be a potential biomarker of dry eye disease (DED)'s severity and prognosis. Given the fact that HLA-DR receptor is a heterodimer consisting in an alpha and a beta chain, we intended to investigate the correlation of inflammatory targets with the corresponding transcripts, HLA-DRA and HLA-DRB1, to characterize specific targets closely related to HLA-DR expressed in conjunctival cells from patients suffering from DED of various etiologies.
Methods: A prospective study was conducted in 88 patients with different forms of DED. Ocular symptom scores, ocular-staining grades, tear breakup time (TBUT) and Schirmer test were evaluated. Superficial conjunctival cells were collected by impression cytology and total RNAs were extracted for analyses using the new NanoString® nCounter technology based on an inflammatory human code set containing 249 inflammatory genes.
Results: Two hundred transcripts were reliably detected in conjunctival specimens at various levels ranging from 1 to 222,546 RNA copies. Overall, from the 88 samples, 21 target genes showed a highly significant correlation (R > 0.8) with HLA-DRA and HLA-DRB1, HLA-DRA and B1 presenting the highest correlation (R = 0.9). These selected targets belonged to eight family groups, namely interferon and interferon-stimulated genes, tumor necrosis factor superfamily and related factors, Toll-like receptors and related factors, complement system factors, chemokines/cytokines, the RIPK enzyme family, and transduction signals such as the STAT and MAPK families.
Conclusions: We have identified a profile of 21 transcripts correlated with HLA-DR expression, suggesting closely regulated signaling pathways and possible direct or indirect interactions between them. The NanoString® nCounter technology in conjunctival imprints could constitute a reliable tool in the future for wider screening of inflammatory biomarkers in DED, usable in very small samples. Broader combinations of biomarkers associated with HLA-DR could be analyzed to develop new diagnostic approaches, identify tighter pathophysiological gene signatures and personalize DED therapies more efficiently.
Introduction
The definition of dry eye disease (DED) has recently been revised to “a multifactorial disease of the ocular surface characterized by a loss of homeostasis of the tear film, and accompanied by ocular symptoms, in which tear film instability and hyperosmolarity, ocular surface inflammation and damage, and neurosensory abnormalities play etiological roles” (1).
Indeed, among the DED definition criteria, its pathogenesis has been largely described as the result of chronic inflammation and activation of the immune system, with involvement of a wide variety of inflammatory mediators, notably chemokines and cytokines (2–5). These markers have been explored in either tears or the conjunctiva (6), such as: Human leukocyte antigen-DR (HLA-DR) (7, 8), Interleukins (ILs): IL-6, IL-1α, IL-8 (9), IL-1β, Matrix Metalloproteinases-9 (MMP-9) (10), Interferon-gamma (IFN-γ), IL-17, and CXCL10 (11).
HLA-DR is a transmembrane heterodimer consisting of alpha (α) and beta (β) glycoprotein chains, and belonging to the major histocompatibility complex (MHC) class II receptors. The α and β chains are encoded by separate genes and their expressions are exquisitely controlled at the transcriptional level (12).They are constitutively expressed by antigen-presenting cells (APCs), such as macrophages, B-lymphocytes, and dendritic cells, but they can also be induced in activated T-lymphocytes and non-professional APCs such as epithelial cells in inflammatory conditions (13).
Using flow cytometry, a technique designed to quantify both levels of expression of a marker by a cell population and the number of cells bearing the targeted protein, HLA-DR was detected in conjunctival epithelial cells obtained by conjunctival imprints (CIs) from DED patients (7). It was reported to be associated with disease severity (14) and correlated with symptoms and signs as corneal fluorescein staining (13). Several multicenter trials have included this methodology as a tool evaluating ocular surface (OS) inflammation (13, 15). Therefore, HLA-DR is now considered as one of the most promising markers of OS inflammation (16, 17).
To better understand the regulatory loop of HLA-DR expression and to investigate the specific inflammatory targets associated with HLA-DR induction, a transcriptomic and multiplexed approach was used on the CIs of ocular surface disease (OSD) patients. Additionally, as the (α/β) heterodimers are the main products of the HLA-DRA and B1genes, respectively, investigations of the gene transcripts correlated with them can contribute to a better understanding of the transcriptional activation and regulation of HLA-DR's complex expression.
Previous transcript analyses were mainly carried out using detection methods as classical PCR, qPCR, RNA-Seq, or microarray (9, 18, 19). In contrast to RNA-Seq, which is based on sequenced RNA converted to a cDNA library, the microarray method is based on the direct detection of the hybridized RNA with labeled probes. Although microarray and RNA-Seq are two major high-throughput technologies for studying RNA expression, these techniques suffer from certain disadvantages such as the presence of background noise. NanoString® technology combines the advantages of both microarray and RNA-Seq with a high resolution and a low level of background noise. It uses digital color-coded bar probes to ensure a multiplexed measurement of gene expression (20). This quantitation method offers a high level of accuracy and sensitivity of individual transcript counts without enzymatic reactions, specifically with a minimal amount of total RNA (21). It is a powerful gene screening technology, used for determining gene expression profiles and has application in molecular-level diagnosis analysis, in several diseases (22).
In this study, we therefore used this new NanoString® nCounter technology to characterize specific inflammatory targets associated with HLA-DR in order to identify related signaling pathways triggered in a conjunctival inflammatory context in DED patients regardless of their underlying etiology.
Materials and Methods
Clinical Evaluation and Specimen Collection
This prospective single-center study was conducted from January 2014 to December 2015 at the Clinical Investigation Centre (CIC INSERM 1423) of the Quinze-Vingts National Ophthalmology Hospital. The study was conducted in accordance with the Declaration of Helsinki (1964) and approved by the CPP–Ile-de-France V Ethics Committee (number 10793). All patients were informed of the aim and methods of the study and gave their consent. The aim of the study was to examine the gene correlation levels with HLA-DR in a DED patient population without consideration on their etiology. In this study, 88 patients were included, 19 males and 69 females, suffering from various causes of DED: primary Sjögren syndrome (pSS, n = 30), meibomian gland dysfunction (MGD, n = 41), allergy-related DED (n = 7), iatrogenic disorders (n = 5), and graves' disease (n = 5). Conjunctival superficial cells were collected using application of a polyether sulfone filter (Supor®, Gelman, Pall Science, Ann Arbor, MI, USA) onto the anesthetized bulbar conjunctiva and immediately put into a 2-mL plastic dry tube and stored at (−80°C) until use.
RNA Isolation From Conjunctival Imprint Cells and Quality Measurement
Total RNAs were extracted from conjunctival cells using an RNA-XS kit from Macherey-Nagel. RNA yield and purity were assessed using NanoDrop ND-100 Spectrophotometer (NanoDrop technologies, Rockland, DE, USA). The RNA purity was assessed using the absorbance ratio between RNA and proteins, read at 260 and 280 nm, respectively (A260/280). Total RNA integrity was evaluated with the Agilent 2100 bioanalyzer (Agilent Technologies, Wilmington, DE, USA) according to the manufacturer's specifications.
An RNA integrity number (RIN) greater than 8 was considered as an acceptable quality criterion for the analysis. The instrument software generates a RIN score based on its entire electropherogram. RIN values range from 1 to 10, from a totally degraded RNA to the highest-quality RNA. A cut-off of RIN = 8.0 was used to ensure good RNA quality. RNA from CIs shows a high quality with a RIN greater than 8 for all samples. Total RNA, with a high RNA quality and purity (A260/280 = 1.8; RIN > 8), isolated from conjunctival cells collected from the 88 DED patients was used for quantitative analysis using the inflammatory NanoString® CodeSet panel.
Nanostring® Ncounter Assay
The gene expression panel (Table 1) was measured in conjunctival cells using a multiplexed hybridization assay and specific fluorescent barcode probes with no amplification step. Inflammatory gene expression was measured with nCounter® human Inflammation v2 CodeSet1 Technologies, Seattle, WA, USA) on the NanoString® nCounter analysis system (NanoString Technologies).
The code set is constituted of biotinylated capture probes and reporter probes attached to color barcode tags for the 249 inflammation-related human genes and six internal reference genes (Table 1). Briefly, purified RNA was diluted in nuclease-free water to 20 ng/μL, making a final assay concentration of 100 ng. Samples were incubated 16–22 h at 65°C as per the manufacturer's standard protocol to ensure hybridization with reporter and capture probes. After hybridization, the samples were processed in the Prep Station and counted in the digital analyzer.
Nanostring Data Analysis
The number of counts from RCC files of each gene in the CodeSet was analyzed using Microsoft Excel software. The number of transcript copies was then normalized using the geometric mean of six reference genes and was log2-transformed for further analysis.
Statistical Analysis
The correlations between the different inflammatory mRNA counts were evaluated with the Spearman correlation test (R) using Graph Pad Prism 7.0 software; R > 0.8 was considered as an appropriate correlation level allowing the selection of targets of interest for accurate gene profiling.
Results
Inflammatory Gene Expression in Conjunctival Cells From DED Patients
NanoString® nCounter analysis covering 249 target genes was used among the 38-gene families (Table 1). Two hundred out of the 249 genes analyzed were detected with more than 50 copies, whereas 49 genes (Table 2) were not detected or were below 50 RNA copies per sample. However, the genes corresponding to the family of Tumor Necrosis Factor (TNF) receptors, Mitogen Activated Protein Kinase (MAPK), and Signal Transducer and Activator of Transcription (STAT) families were detected in all DED patient sub groups.
Table 2. List of undetected inflammatory genes in conjunctival cells from CI samples collected in DED patients.
Correlations of Detected Inflammatory Mediators With Both HLA-DRA/B1 Receptor Transcripts
We next investigated the pairwise Spearman correlation among the 200 genes detected and their relationships with both HLA-DR receptors HLA-DRA and HLA-DRB1. Of the 200 genes detected, 21 displayed correlations higher than 0.8 with both HLA-DR (Tables 3A,B). The related inflammatory transcripts included: IRF1, IFI44, HDH2D, Mx1, OAS2, CD40, TRAF2, TRADD,TLR2, TLR3, MyD88, CL22, IL15, C2, CFB, RIPK2, STAT1, STAT2, STAT3, MAPK8, and MAPKAP2, with a highly positive and significant correlation (R > 0.8, p < 0.0001***). These inflammatory targets belonged to eight major families: (1) IFN and interferon-stimulating genes (ISGs), (2) TNF superfamily, (3) the receptor interacting protein kinase family (RIPK), (4) chemokines/cytokines, (5) toll-like receptors, (6) complement and complement regulatory proteins (CRPs), (7) STAT (8) MAPK families. Finally, HLA-DRA and HLA-DRB1 displayed a very high significant correlation between them (R = 0.90, p < 0.0001***). Figure 1 shows the distribution of each gene on the whole sample population as related to its family.
Table 3. Selected inflammatory targets displaying a high correlation with HLA-DRA and HLA-B1 in conjunctival cells.
Figure 1. RNA abundance of the selected highly correlated genes with both HLA-DR transcripts according to their family. RNA abundance is represented by the detected RNA copies on the y-axis. Numbers above the hatched rectangle correspond to each target family selected: (1) IFN and ISGs, (2) TNF superfamily, (3) TLR and related factors, (4) chemokines/cytokines, (5) complement and CRP (6) RIPK enzymes, (7) STAT, (8) MAPK.
Differential Distribution of Inflammatory Genes in Patients With Sjögren Syndrome Dry Eye (SSDE) and Non-SjöGren Syndrome Dry Eye (NSSDE)
Following selection of the highly correlated (R > 0.8) inflammatory targets with both HLA-DR transcripts, in the whole population (n = 88), we wanted to investigate the differential correlated genes between the two major groups of patients; group 1 (SSDE, n = 30) and group 2 (NSSDE, n = 58) according to their correlation with HLA-DRA and HLA-DRB1. As upper described, a pairwise Spearman correlation among the 200 genes detected with both HLA-DR receptors HLA-DRA and HLA-DRB1 were applied. Figures 2A,B shows in ascending manner, the genes significantly correlated with both HLA-DRA and HLA-DRB1 in group 1 and group 2. Group 1 (SSDE) present more genes correlated with both HLA-DR (A/B1) than group 2 (NSSDE), with 102 genes vs. 80 genes, respectively. Among the correlated genes, 59 genes were common between both groups while 43 and 21 genes differentially correlated genes with group 1 (SSDE) and group 2 (NSSDE), respectively (Figure 2C).
Figure 2. Correlation analysis of genes with HLA-DRA and HLA-DRB1 based on the Spearman's correlation coefficients of genes in SSDE and NSSDE patients. (A,B) Represent Heat Map of genes significantly (P < 0.05) correlated with both HLA-DR-A and HLA-DRB1, in a descending manner. (C) Venn diagram showing the number of specific and common targets identified in the two groups of patients. SSDE, syndrome Sjögren dry eye; NSSDE, non syndrome Sjögren dry eye.
Discussion
In this study, we aimed to describe tissue-specific transcriptional networks associated with HLA-DR expression in conjunctival cells of patients with DED stemming from various causes. Presence of HLA-DR is important in inflammatory cells for antigen presentation to CD4 T cells but in epithelial cells, antigen presentation is unlikely and HLA-DR has been considered in the last decades of research in ocular surface diseases mainly as a marker of the inflammatory state, of its level and possibly its mechanisms. The CIs are biological specimens of small size with rare cells compared to blood samples or other tissue samples. The Nanostring technology applied to CIs allows the investigation of numerous targets in only one imprint. CIs provide 3 main cell types from the superficial conjunctival layers with a majority of epithelial cells (more than 90%), followed by goblet cells and inflammatory/immune cells (mainly lymphocytes and dendritic cells). The numbers of these latter cells can also vary considerably according to the level of inflammation, so the source of HLA-DR in relation with a specific function, i.e., activation vs regulation, cannot be fully assessed. Nevertheless, whatever the cell type, these gene expressions reflect the reality of the presence of a local inflammatory stimulation and its relation to HLA-DR. As mentioned above, the pathophysiology of OSD and especially DED is complex and not yet fully understood, but DED is largely recognized as being associated with OS inflammation, resulting in symptoms of eye irritation, alteration of conjunctival and corneal epithelial cells, and corneal barrier dysfunction (1–3, 5, 55).
Considering the complexity of DED diagnosis in terms of clinical criteria, signs and symptoms, many studies, for more than 30 years, have been conducted trying to find reliable biological markers correlated with pathophysiological disease patterns. Here, we have investigated 249 mRNA targets known to be involved in inflammation using the NanoString® technology, considering the extensively reported studies examining the relationships between inflammation and DED (2, 5). Therefore, based on the interest raised by HLA-DR expression in DED patients and the usefulness of measuring this marker in clinical trials for investigating the level of inflammation (13), we focused particularly on the relationships of HLA-DRA and HLA-DRB1 transcripts of HLA-DR heterodimers α and β (23) with inflammatory genes.
Our results highlighted the expression of a large variety of inflammation-related mediators in conjunctival cells from DED patients. Among the 200 transcripts found to be expressed in conjunctival cells, we focused on those with the strongest correlations with the two HLA-DR transcripts. For that purpose we used very strict criteria, only selecting as markers of interest those with correlation coefficients above 0.8. This allows us to reduce correlation background noise and focus on families of mediators and pathways most likely to play a role in HLA-DR-related cascades of activation. These markers belong to the IFN, TLR, and TNF signaling pathways mediated by STATs and MAPKs, and to the complement and cytokine families (Tables 3A,B). The main interest shown by these results is that in addition to having several targets correlated with HLA-DR, these targets could be integrated into common signaling pathways. Figure 3 summarizes the signaling pathways associated with HLA-DR overexpression in conjunctival cells. Our data confirm the role of IFN, TLR, and TNF pathways, and highlight their close interactions. Indeed, the association of these three families with HLA-DR was previously demonstrated in studies reporting the implication of IFN, TLR, and TNF pathways in molecular processes induced at the cellular level during DED (35, 56, 57).
Figure 3. Proposal for a pattern of signaling pathways associated with increased HLA-DR expression in conjunctival cells. This figure presents the localization of the targets identified with their possible interactions in the conjunctiva's spatial microenvironment. The four major signaling responses, in black circles, are mediated by (1) TLR responses, (2) IFN responses, (3) TNF responses, and (4) members of complement pathways. The target genes selected via their high correlation with HLA-DR are mentioned in bold red. The first line of pathogen recognition could be mediated by TLR responses via MAPK and NF-κB to induce inflammatory cytokine responses as INFs. IFNs bind to their receptors and initiate a signaling cascade, involving the JAK-STAT family of transcription factors, which leads to the transcriptional induction of the ISGs (IRF-1, IFI-44, HSH2D, Mx1, and OAS2), class II transactivator (CII-TA), and HLA-DR complex, which will migrate to the membrane. CD40, TRAF2, TRADD, and RIPK2, involved in TNF pathways, promote NF-κB and the MAPK family: MK2 and MAPK8, members of the p38 MAPK and JNK cascades, respectively. Pathogen-associated molecular patterns (PAMPs); CCAAT/enhancer binding protein beta(C/EBPβ); AP-1 transcription factor subunit(AP−1); IFN regulatory factor IRF-3 and IRF-7(IRF3/7); IFN-stimulated response element (ISRE); IFNγ-activated site (GAS); phosphate(P); class II transactivator (CIITA); MHC class II-specific regulatory module (XYS); nuclear factor kappa B subunit 2(p52); NF-κB subunit transcription factor RelB (RelB).
Nevertheless, the most representative targets were those associated with IFN signaling, represented by IRF-1 (24), IFI-44 (25–27), HSH2D (28, 29), Mx1 (30–32), and OAS2 (33, 34). These ISGs are induced by the three types of IFNs, type I IFNs (IFNα and IFNβ), type II IFN (IFNγ), and type III IFN (IFNλ) (Table 3B). IFNs bind to their cognate receptors and initiate a signaling cascade, involving the JAK family of tyrosine kinases and the STAT family of transcription factors, which leads to the transcriptional induction of the ISGs. Cellular actions of IFNs are largely mediated by the proteins encoded by ISGs, which have important roles in innate immunity against different families of microorganisms. Previous studies reported that the expression of HLA-DR in conjunctival cells might be regulated by IFNγ (57, 58). Indeed, IFNγ induces class II transactivator (CII-TA) expression on different cell types such as epithelial cells, thus stimulating the up-regulation of class II molecules, such as HLA-DR via the SXY module present in all classical MHC class II genes (59).
However, no investigation has yet been conducted on the regulation of these ISGs on HLA-DR expression or on their role in conjunctival cells during DED. Interestingly, IRF-1 was found to be increased in human corneal epithelial cells (HCECs) after a Pseudomonas aeruginosa bacterial challenge (60) and seems to be essential for MHC class II gene expression, as described in the mouse macrophage cell line RAW264.7 (61). Moreover, the down-regulation of MHC II gene expression in primary microglial cells by minocycline was reported as mediated by preventing the nuclear translocation of IRF-1 (62). IFI-44 was found up-regulated in the peripheral blood and minor salivary glands of SS patients (63, 64) and displays an anti-proliferative activity in human melanoma cell lines (65). MX1 and OAS2 were also detected in the blood of patients with an autoimmune disease, namely systemic lupus erythematous disease, in which their roles were not totally defined (66). HSH2D is able to inhibit IL-2 in Jurkat T cells (67) and its transcripts were found up-regulated in primary airway epithelial cells by IFN type I and III (68). Thus, the association of IRF-1, IFI-44, Mx1, OAS2, and HSH2D with HLA-DR could suggest a possible relationship between viral infection and HLA-DR expression.
The second family group found to be correlated with HLA-DR was TLR members and effectors. This confirms the well-described close relation between IFN and TLR, in the ocular surface inflammatory context, through an autocrine loop that amplifies the IFN response (35, 69). TLRs that recognize pathogen-associated molecular patterns (PAMPs) trigger innate immune responses by activating signaling pathways dependent on the MyD88 adaptors and then induce the expression of type I IFNs, pro-inflammatory cytokines, chemokines, and antimicrobial proteins. Hence, TLR members contribute in the exacerbation of various ocular surface inflammatory processes during infection (36, 37). TLR2 and TLR3 as cell surface and intracellular receptors, respectively (38, 39), are also expressed in human limbal and conjunctival epithelial cells and were demonstrated to play a role in cytokine secretion (69, 70). IFNγ induced TLR2 in ex vivo conjunctival cells (36) and TLR3 agonist induced the expression of IFN-β, Mx1 and OAS2 in human corneal epithelial cells (71). The up-regulation of TLR2 and TLR3 may confer an enhanced ability for pathogen recognition, whereas their reduced expression may lead to an inadequate response and therefore an increased risk of infection (35).
In addition to the correlation of TLR and IFN cell signaling members with HLA-DR, the TNF signaling pathway (40), through CD40 (41), TRAF2 (42, 43), TRADD (44), and RIPK2 (45, 46), also seems to be involved in this complex loop of regulation. This latter pathway is mediated by CD40 transduction signal via CD40-TRAF2 to promote nuclear factor-kappa B (NF-κB) and the mitogen-activated protein kinase (MAPK) family (72). TRADD also has a TRAF-binding motif that leads to the recruitment of TRAF1/2, and RIPK2 was described to modulate inflammasome activation through autophagy (45). The interaction between TRADD and RIPK2 with its death domain and C-terminal caspase activation and recruitment domain (CARD), respectively, promotes apoptotic signals (Figure 3).
These results support the idea that the main function of CD40 as a co-stimulatory molecule involved in APC-T-cell interactions is presumably amplified by downstream adaptor proteins, TRAF2, and TRADD. Overexpression of TRAF2 is sufficient to activate NF-κB and AP-1 in the absence of extracellular stimuli (73). Overexpression of TRADD leads to two major TNF-induced responses, apoptosis and activation of NF-κB, by inducing effectors caspase such a caspase-3/7, causing apoptosis (74). We could postulate that these induced signals do not act simultaneously in conjunctival cells, but proceed by sequential steps. Furthermore, previous studies demonstrated that CD40 expression was up-regulated in inflammatory eyes and positively correlated with HLA-DR (75), and was significantly reduced after cyclosporine A, an anti-inflammatory and immunosuppressive treatment (76). This confirms the findings from a previous study showing the association of apoptosis with HLA-DR induction (77), and the key role of apoptosis in the pathogenesis of DED (78). These findings highlight the pivotal role of IFN and TNF responses in the development of a cell-mediated immune response, with a specific interaction of the downstream target with HLA-DR in DED.
As expected, these transduction signals were associated with the well-conserved signaling MAPKs pathways, which promote the expression of inflammatory cytokines and chemokines. In this study, two of them: MAPKAPK2 (47, 48) and MAPK8 (49), members of the p38 MAPK and JNK cascades, respectively, were specifically selected according to their correlation with HLA-DR transcripts. Interestingly, MAPKAPK2 (MK2) is designed as an emerging therapeutic target, as once inhibited, it is able to block the production of IL-1, TNFα, and other cytokines (79), and MK2-deficient mice showed a reduction of IL-6 and TNFα production (80). More interestingly, a recent study conducted on the effect of the MK2 inhibitor on a mice model of dry eye showed a suppression of cell apoptosis and a decrease of MMP3 and MMP9 in corneal epithelium. Also, SB203580, a selective p38-MAPK inhibitor, showed therapeutic effects on dry eye in a mouse model of Sjögren syndrome (MRL/lpr mice) (81). MAPK8 (JNK1) was also investigated in a mouse model of dry eye, showing an increased level of phosphorylated JNK1/2 in the corneal and conjunctival epithelia (82). Finally, JAK and STAT signaling pathways are closely related to HLA-DR as its expression is modulated in conjunctival cells after treatment of DED patients with tofacitinib (CP-690, 550), a selective inhibitor of the Janus kinase (JAK, JAK1-3) (83).
The remaining targets implicated in inflammatory process and belonging to the STAT family: STAT1, STAT2, STAT3 (50), chemokines/cytokines: CCL22 (51) and IL15 (52), complement and CRP:C2 (53) and CFB (54) were briefly described in Table 3B.
The second part of this study gives a brief overview of correlated genes specifically associated with the two major pathological groups as SSDE and NSSDE. As expected the SSDE group presents more genes correlated with HLA-DR than the NSSDE group. More interestingly, 43 and 21 selective genes are only associated with SSDE and NSSDE respectively. These results highlight that the conjunctival profile of HLA-DR correlated genes with SSDE and NSSDE patients present some differences in molecular inflammatory responses.
Among these selective genes for SSDE, MMP9 (R = 0.6), Transforming growth factor beta (TGFB) (R = 0.46), and CCL3 (R = 0.44), present a particular interest to distinguish inflammatory responses and for therapy management especially in SSDE group. TGF-β is known to regulate the immune system, and enhance the synthesis and deposition of extracellular matrix, during wound repair (84). As previously described, level of TGF-β1 mRNA within the conjunctival epithelium of patients with SS is higher when compared to non-DE controls (9) and its bioactivity increases in tears (85). MMP-9 has important roles in the DED inflammatory process (86), likewise tears and saliva of SS patients contain high levels of MMP-9 (9). Finally, tear expression of CCL3 was reported to be increased in DE patients compared to healthy control subjects, especially in those with SS (87) and CCR5 receptor of CCL3 is positively correlated with HLA-DR in conjunctival cells of patients (88); it is also known also that CCL3 shows a significant distribution in salivary of pSS compared to non-SS sicca (89). More interestingly among the genes correlated with HLA-DR in both SS and NSS groups, two of them present an inverse correlation with HLA-DR in the two groups. As: High-mobility group nucleosome-binding protein 1 (HMGN1) (R = −0.45 in SSDE) and (R = 0.43 in NSSDE) followed by Cell division cycle 42 (CDC42) (R = −0.43 in SSDE) and (R = 0.44 in NSSDE). HMGN1 is a member of the HMGN family of proteins that bind specifically to nucleosomes and is known to affect chromatin structure and function, including transcription and DNA repair (90). It is also described to act as a novel alarmin critical for LPS induced development of innate and adaptive immune response (91). Cdc42 is a small GTPase of the Rho family, has pivotal functions in cell migration and proliferation, and is known to be essential for human T-cell development, where loss of expression induces apoptosis and reduced proliferation (92). Even if these genes display a mild correlation of R = 0.4, the mirror suggested effect, could be interesting for further investigation concerning the molecular responses associated with HLA-DR in an autoimmune and non-autoimmune context of DED. Indeed, at this stage of the investigation, we cannot hypothesize to a functional role corresponding of this loss of expression in presence of high level of HLA-DR in SSDE, but we only point out the deleterious effect of this target in presence of high level of inflammation especially in case of severe DED. This could be also helpful in managing SSDE and NSSDE with anti-inflammatory therapy (93).
In summary, this original work highlights the implication of a large set of inflammatory mediators in DED with the same tendency as with two HLA-DR forms (A and B1). All these identified target genes could work in concert in a spatial microenvironment to efficiently promote cell recruitment and maintain an inflammatory state in conjunctival cells (Figure 3). This combination of genes associated with HLA-DR corresponds to biologically meaningful modules in a network, which could become future candidates for drug development. These outcomes also support the assumption that inflammation is a core pathophysiological process in DED, maintaining a vicious circle of inflammation, and a self-perpetuating cycle ensues (4). Moreover, the nCounter analysis system from NanoString® technologies applied on CIs is a reliable tool for multiplexed gene expression analysis of the inflammatory biomarkers in DED, and more generally other OSDs, especially when only tiny samples are available. This tool was applied in ophthalmology for the first time and is a powerful tool for the detection of specific molecular targets. This methodology expands the repertoire of approaches for expression profiling and offers several advantages over existing technologies, as it requires less sample material, has no enzymatic bias, and provides a direct digital readout. As yet, however, no single protein or panel of markers has been shown to discriminate between the major forms of DED. The gene expression profiling could contribute to understanding more fully the discrepancy between signs and symptoms in DED (94) and the failure of some therapies. Although this transcriptomic platform is still in its early stages in clinical use, especially in the cancer biology field (95, 96), it is expected that NanoString®-based inflammatory expression panels can play a more important role in the future for classifying DED patients and predicting their response to different treatment strategies. Finally, these molecular actors, selected upon a high level of correlation with HLA-DR, could improve our knowledge on the pathophysiology of DED, for a better understanding of the underlying regulation loop and to define their role in conjunctival cells and the ocular surface.
Author Contributions
CB, FB-B, KK, PD, and J-SG designed the study and planned the experiments. CB, HL, and GR supervised the clinical part for the recruitment of the patients and clinical data analysis. KK and MD performed experiments and transcriptomic data interpretation. FB-B, KK, and PD wrote the manuscript. CB, FB-B and SMP aided in interpreting the results and worked on the manuscript. All authors discussed the results and commented on the manuscript.
Funding
This study was funded by Sorbonne Université - Université Pierre and Marie Curie (UPMC), the Institut National de la Santé et de la Recherche Médicale, Centre Hospitalier National d'Ophtalmologie des 15–20 and Santen SAS.
Conflict of Interest Statement
J-SG and PD are Santen SAS employees. CB is consultant for Santen SAS.
The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Acknowledgments
We thank Linda Northrup for editing advice.
Footnotes
References
1. Craig JP, Nichols KK, Akpek EK, Caffery B, Dua HS, Joo CK, et al. TFOS DEWS II definition and classification report. Ocul Surf. (2017) 15:276–83. doi: 10.1016/j.jtos.2017.05.008
2. Barabino S, Chen Y, Chauhan S, Dana R. Ocular surface immunity: homeostatic mechanisms and their disruption in dry eye disease. Prog Retin Eye Res. (2012) 31:271–85. doi: 10.1016/j.preteyeres.2012.02.003
3. Stern ME, Schaumburg CS, Pflugfelder SC. Dry eye as a mucosal autoimmune disease. Int Rev Immunol. (2013) 32:19–41. doi: 10.3109/08830185.2012.748052
4. Baudouin C, Aragona P, Messmer EM, Tomlinson A, Calonge M, Boboridis KG, et al. Role of hyperosmolarity in the pathogenesis and management of dry eye disease: proceedings of the OCEAN group meeting. Ocul Surf. (2013) 11:246–58. doi: 10.1016/j.jtos.2013.07.003
5. Hessen M, Akpek EK. Dry eye: an inflammatory ocular disease. J Ophthalmic Vis Res. (2014) 9:240–50.
6. Stevenson W, Chauhan SK, Dana R. Dry eye disease: an immune-mediated ocular surface disorder. Arch Ophthalmol. (2012) 130:90–100. doi: 10.1001/archophthalmol.2011.364
7. Baudouin C, Brignole F, Becquet F, Pisella PJ, Goguel A. Flow cytometry in impression cytology specimens. a new method for evaluation of conjunctival inflammation Invest Ophthalmol Vis Sci. (1997) 38:1458–64.
8. Baudouin C, Brignole F, Pisella PJ, De Jean MS, Goguel A. Flow cytometric analysis of the inflammatory marker HLA-DR in dry eye syndrome: results from 12 months of randomized treatment with topical cyclosporin A. Adv Exp Med Biol. (2002) 506:761–9. doi: 10.1007/978-1-4615-0717-8_107
9. Pflugfelder SC, Jones D, Ji Z, Afonso A, Monroy D. Altered cytokine balance in the tear fluid and conjunctiva of patients with Sjogren's syndrome keratoconjunctivitis sicca. Curr Eye Res. (1999) 19:201–11. doi: 10.1076/ceyr.19.3.201.5309
10. Solomon A, Dursun D, Liu Z, Xie Y, Macri A, Pflugfelder SC. Pro- and anti-inflammatory forms of interleukin-1 in the tear fluid and conjunctiva of patients with dry-eye disease. Invest Ophthalmol Vis Sci. (2001) 42:2283–92.
11. Enriquez-de-Salamanca A, Castellanos E, Stern ME, Fernandez I, Carreno E, Garcia-Vazquez C, et al. Tear cytokine and chemokine analysis and clinical correlations in evaporative-type dry eye disease. Mol Vis. (2010) 16:862–73.
12. Ting JP, Trowsdale J. Genetic control of MHC class II expression. Cell (2002) 109(Suppl.):S21–33. doi: 10.1016/S0092-8674(02)00696-7
13. Brignole-Baudouin F, Riancho L, Ismail D, Deniaud M, Amrane M, Baudouin C. Correlation between the inflammatory marker HLA-DR and signs and symptoms in moderate to severe dry eye disease. Invest Ophthalmol Vis Sci. (2017) 58:2438–48. doi: 10.1167/iovs.15-16555
14. Tsubota K, Fujihara T, Saito K, Takeuchi T. Conjunctival epithelium expression of HLA-DR in dry eye patients. Ophthalmologica (1999) 213:16–9. doi: 10.1159/000027387
15. Brignole-Baudouin F, Ott AC, Warnet JM, Baudouin C. Flow cytometry in conjunctival impression cytology: a new tool for exploring ocular surface pathologies. Exp Eye Res. (2004) 78:473–81. doi: 10.1016/j.exer.2003.08.005
16. Rolando M, Barabino S, Mingari C, Moretti S, Giuffrida S, Calabria G. Distribution of conjunctival HLA-DR expression and the pathogenesis of damage in early dry eyes. Cornea (2005) 24:951–4. doi: 10.1097/01.ico.0000157421.93522.00
17. Roy NS, Wei Y, Kuklinski E, Asbell PA. The growing need for validated biomarkers and endpoints for dry eye clinical research. Invest Ophthalmol Vis Sci. (2017) 58:BIO1–19. doi: 10.1167/iovs.17-21709
18. Kawasaki S, Kawamoto S, Yokoi N, Connon C, Minesaki Y, Kinoshita S, et al. Up-regulated gene expression in the conjunctival epithelium of patients with Sjogren's syndrome. Exp Eye Res. (2003) 77:17–26. doi: 10.1016/S0014-4835(03)00087-3
19. Bradley JL, Edwards CS, Fullard RJ. Adaptation of impression cytology to enable conjunctival surface cell transcriptome analysis. Curr Eye Res. (2014) 39:31–41. doi: 10.3109/02713683.2013.823213
20. Geiss GK, Bumgarner RE, Birditt B, Dahl T, Dowidar N, Dunaway DL, et al. Direct multiplexed measurement of gene expression with color-coded probe pairs. Nat Biotechnol. (2008) 26:317–25. doi: 10.1038/nbt1385
21. Veldman-Jones MH, Brant R, Rooney C, Geh C, Emery H, Harbron CG, et al. Evaluating robustness and sensitivity of the nanostring technologies ncounter platform to enable multiplexed gene expression analysis of clinical samples. Cancer Res. (2015) 75:2587–93. doi: 10.1158/0008-5472.CAN-15-0262
22. Tsang HF, Xue VW, Koh SP, Chiu YM, Ng LP, Wong SC. NanoString, a novel digital color-coded barcode technology: current and future applications in molecular diagnostics. Expert Rev Mol Diagn. (2017) 17:95–103. doi: 10.1080/14737159.2017.1268533
23. Stern LJ, Brown JH, Jardetzky TS, Gorga JC, Urban RG, Strominger JL, et al. Crystal structure of the human class II MHC protein HLA-DR1 complexed with an influenza virus peptide. Nature (1994) 368:215–21. doi: 10.1038/368215a0
24. Savitsky D, Tamura T, Yanai H, Taniguchi T. Regulation of immunity and oncogenesis by the IRF transcription factor family. Cancer Immunol Immunother. (2010) 59:489–510. doi: 10.1007/s00262-009-0804-6
25. Kitamura A, Takahashi K, Okajima A, Kitamura N. Induction of the human gene for p44, a hepatitis-C-associated microtubular aggregate protein, by interferon-alpha/beta. Eur J Biochem. (1994) 224:877–83. doi: 10.1111/j.1432-1033.1994.00877.x
26. Power D, Santoso N, Dieringer M, Yu J, Huang H, Simpson S, et al. IFI44 suppresses HIV-1 LTR promoter activity and facilitates its latency. Virology (2015) 481:142–50. doi: 10.1016/j.virol.2015.02.046
27. Takeuchi O, Akira S. Recognition of viruses by innate immunity. Immunol Rev. (2007) 220:214–24. doi: 10.1111/j.1600-065X.2007.00562.x
28. Oda T, Muramatsu MA, Isogai T, Masuho Y, Asano S, Yamashita T. HSH2: a novel SH2 domain-containing adapter protein involved in tyrosine kinase signaling in hematopoietic cells. Biochem Biophys Res Commun. (2001) 288:1078–86. doi: 10.1006/bbrc.2001.5890
29. Liu BA, Jablonowski K, Raina M, Arce M, Pawson T, Nash PD. The human and mouse complement of SH2 domain proteins-establishing the boundaries of phosphotyrosine signaling. Mol Cell. (2006) 22:851–68. doi: 10.1016/j.molcel.2006.06.001
30. Sadler AJ, Williams BR. Interferon-inducible antiviral effectors. Nat Rev Immunol. (2008) 8:559–68. doi: 10.1038/nri2314
31. Haller O, Stertz S, Kochs G. The Mx GTPase family of interferon-induced antiviral proteins. Microbes Infect. (2007) 9:1636–43. doi: 10.1016/j.micinf.2007.09.010
32. Haller O, Staeheli P, Kochs G. Interferon-induced Mx proteins in antiviral host defense. Biochimie (2007) 89:812–8. doi: 10.1016/j.biochi.2007.04.015
33. Tanaka N, Nakanishi M, Kusakabe Y, Goto Y, Kitade Y, Nakamura KT. Structural basis for recognition of 2',5'-linked oligoadenylates by human ribonuclease L. EMBO J. (2004) 23:3929–38. doi: 10.1038/sj.emboj.7600420
34. Hovanessian AG. On the discovery of interferon-inducible, double-stranded RNA activated enzymes: the 2'-5'oligoadenylate synthetases and the protein kinase PKR. Cytokine Growth Factor Rev. (2007) 18:351–61. doi: 10.1016/j.cytogfr.2007.06.003
35. Redfern RL, Reins RY, McDermott AM. Toll-like receptor activation modulates antimicrobial peptide expression by ocular surface cells. Exp Eye Res. (2011) 92:209–20. doi: 10.1016/j.exer.2010.12.005
36. Cook EB, Stahl JL, Esnault S, Barney NP, Graziano FM. Toll-like receptor 2 expression on human conjunctival epithelial cells: a pathway for Staphylococcus aureus involvement in chronic ocular proinflammatory responses. Ann Allergy Asthma Immunol. (2005) 94:486–97. doi: 10.1016/S1081-1206(10)61120-9
37. Bonini S, Micera A, Iovieno A, Lambiase A, Bonini S. Expression of Toll-like receptors in healthy and allergic conjunctiva. Ophthalmology (2005) 112:1528 discussion 48-9. doi: 10.1016/j.ophtha.2005.04.009
38. Kawasaki T, Kawai T. Toll-like receptor signaling pathways. Front Immunol. (2014) 5:461. doi: 10.3389/fimmu.2014.00461
39. Matsumoto M, Funami K, Tanabe M, Oshiumi H, Shingai M, Seto Y, et al. Subcellular localization of Toll-like receptor 3 in human dendritic cells. J Immunol. (2003) 171:3154–62. doi: 10.4049/jimmunol.171.6.3154
40. Sabio G, Davis RJ. TNF and MAP kinase signalling pathways. Semin Immunol. (2014) 26:237–45. doi: 10.1016/j.smim.2014.02.009
41. van Kooten C, Banchereau J. CD40-CD40 ligand. J Leukoc Biol. (2000) 67:2–17. doi: 10.1002/jlb.67.1.2
42. Pullen SS, Miller HG, Everdeen DS, Dang TT, Crute JJ, Kehry MR. CD40-tumor necrosis factor receptor-associated factor (TRAF) interactions: regulation of CD40 signaling through multiple TRAF binding sites and TRAF hetero-oligomerization. Biochemistry (1998) 37:11836–45. doi: 10.1021/bi981067q
43. Pullen SS, Labadia ME, Ingraham RH, McWhirter SM, Everdeen DS, Alber T, et al. High-affinity interactions of tumor necrosis factor receptor-associated factors (TRAFs) and CD40 require TRAF trimerization and CD40 multimerization. Biochemistry (1999) 38:10168–77. doi: 10.1021/bi9909905
44. Micheau O, Tschopp J. Induction of TNF receptor I-mediated apoptosis via two sequential signaling complexes. Cell (2003) 114:181–90. doi: 10.1016/S0092-8674(03)00521-X
45. Lupfer C, Thomas PG, Anand PK, Vogel P, Milasta S, Martinez J, et al. Receptor interacting protein kinase 2-mediated mitophagy regulates inflammasome activation during virus infection. Nat Immunol. (2013) 14:480–8. doi: 10.1038/ni.2563
46. Hsu H, Huang J, Shu HB, Baichwal V, Goeddel DV. TNF-dependent recruitment of the protein kinase RIP to the TNF receptor-1 signaling complex. Immunity (1996) 4:387–96. doi: 10.1016/S1074-7613(00)80252-6
47. Raingeaud J, Gupta S, Rogers JS, Dickens M, Han J, Ulevitch RJ, et al. Pro-inflammatory cytokines and environmental stress cause p38 mitogen-activated protein kinase activation by dual phosphorylation on tyrosine and threonine. J Biol Chem. (1995) 270:7420–6. doi: 10.1074/jbc.270.13.7420
48. Menon MB, Tiedje C, Lafera J, Ronkina N, Konen T, Kotlyarov A, et al. Endoplasmic reticulum-associated ubiquitin-conjugating enzyme Ube2j1 is a novel substrate of MK2 (MAPKAP kinase-2) involved in MK2-mediated TNFalpha production. Biochem J. (2013) 456:163–72. doi: 10.1042/BJ20130755
49. Roberts ML, Cowsert LM. Interleukin-1 beta and reactive oxygen species mediate activation of c-Jun NH2-terminal kinases, in human epithelial cells, by two independent pathways. Biochem Biophys Res Commun. (1998) 251:166–72. doi: 10.1006/bbrc.1998.9434
50. Glimcher LH, Murphy KM. Lineage commitment in the immune system: the T helper lymphocyte grows up. Genes Dev. (2000) 14:1693–711. doi: 10.1101/gad.14.14.1693
51. Wysocki CA, Panoskaltsis-Mortari A, Blazar BR, Serody JS. Leukocyte migration and graft-versus-host disease. Blood (2005) 105:4191–9. doi: 10.1182/blood-2004-12-4726
52. Carson WE, Ross ME, Baiocchi RA, Marien MJ, Boiani N, Grabstein K, et al. Endogenous production of interleukin 15 by activated human monocytes is critical for optimal production of interferon-gamma by natural killer cells in vitro. J Clin Invest. (1995) 96:2578–82. doi: 10.1172/JCI118321
53. Frank MM, Fries LF. The role of complement in inflammation and phagocytosis. Immunol Today. (1991) 12:322–6. doi: 10.1016/0167-5699(91)90009-I
55. Baudouin C, Irkec M, Messmer EM, Benitez-Del-Castillo JM, Bonini S, Figueiredo FC, et al. Clinical impact of inflammation in dry eye disease: proceedings of the ODISSEY group meeting. Acta Ophthalmol. (2018) 96:111–9. doi: 10.1111/aos.13436
56. Stern ME, Pflugfelder SC. Inflammation in dry eye. Ocul Surf . (2004) 2:124–30. doi: 10.1016/S1542-0124(12)70148-9
57. Tsubota K, Fukagawa K, Fujihara T, Shimmura S, Saito I, Saito K, et al. Regulation of human leukocyte antigen expression in human conjunctival epithelium. Invest Ophthalmol Vis Sci. (1999) 40:28–34.
58. Calonge M, De Salamanca AE, Siemasko KF, Diebold Y, Gao J, Juarez-Campo M, et al. (2005). Variation in the expression of inflammatory markers and neuroreceptors in human conjunctival epithelial cells. Ocul Surf. 3(4 Suppl.):S145–8. doi: 10.1016/S1542-0124(12)70241-0
59. Reith W, LeibundGut-Landmann S, Waldburger JM. Regulation of MHC class II gene expression by the class II transactivator. Nat Rev Immunol. (2005) 5:793–806. doi: 10.1038/nri1708
60. Yoon GS, Dong C, Gao N, Kumar A, Standiford TJ Yu FS. Interferon regulatory factor-1 in flagellin-induced reprogramming: potential protective role of CXCL10 in cornea innate defense against Pseudomonas aeruginosa infection. Invest Ophthalmol Vis Sci. (2013) 54:7510–21. doi: 10.1167/iovs.13-12453
61. Giroux M, Schmidt M, Descoteaux A. IFN-gamma-induced MHC class II expression: transactivation of class II transactivator promoter IV by IFN regulatory factor-1 is regulated by protein kinase C-alpha. J Immunol. (2003) 171:4187–94. doi: 10.4049/jimmunol.171.8.4187
62. Nikodemova M, Watters JJ, Jackson SJ, Yang SK, Duncan ID. Minocycline down-regulates MHC II expression in microglia and macrophages through inhibition of IRF-1 and protein kinase C (PKC)alpha/betaII. J Biol Chem. (2007) 282:15208–16. doi: 10.1074/jbc.M611907200
63. Hjelmervik TO, Petersen K, Jonassen I, Jonsson R, Bolstad AI. Gene expression profiling of minor salivary glands clearly distinguishes primary Sjogren's syndrome patients from healthy control subjects. Arthritis Rheum. (2005) 52:1534–44. doi: 10.1002/art.21006
64. Emamian ES, Leon JM, Lessard CJ, Grandits M, Baechler EC, Gaffney PM, et al. Peripheral blood gene expression profiling in Sjogren's syndrome. Genes Immun. (2009) 10:285–96. doi: 10.1038/gene.2009.20
65. Hallen LC, Burki Y, Ebeling M, Broger C, Siegrist F, Oroszlan-Szovik K, et al. Antiproliferative activity of the human IFN-alpha-inducible protein IFI44. J Interferon Cytokine Res. (2007) 27:675–80. doi: 10.1089/jir.2007.0021
66. Feng X, Huang J, Liu Y, Xiao L, Wang D, Hua B, et al. Identification of interferon-inducible genes as diagnostic biomarker for systemic lupus erythematosus. Clin Rheumatol. (2015) 34:71–9. doi: 10.1007/s10067-014-2799-4
67. Greene TA, Powell P, Nzerem C, Shapiro MJ, Shapiro VS. Cloning and characterization of ALX, an adaptor downstream of CD28. J Biol Chem. (2003) 278:45128–34. doi: 10.1074/jbc.M306283200
68. Lauber C, Vieyres G, Terczynska-Dyla E, Anggakusuma Dijkman R, Gad HH, et al. Transcriptome analysis reveals a classical interferon signature induced by IFNlambda4 in human primary cells. Genes Immun. (2015) 16:414–21. doi: 10.1038/gene.2015.23
69. Redfern RL, McDermott AM. Toll-like receptors in ocular surface disease. Exp Eye Res. (2010) 90:679–87. doi: 10.1016/j.exer.2010.03.012
70. Li J, Shen J, Beuerman RW. Expression of toll-like receptors in human limbal and conjunctival epithelial cells. Mol Vis. (2007) 13:813–22.
71. Kumar A, Zhang J, Yu FS. Toll-like receptor 3 agonist poly (I:C)-induced antiviral response in human corneal epithelial cells. Immunology (2006) 117:11–21. doi: 10.1111/j.1365-2567.2005.02258.x
72. Arch RH, Gedrich RW, Thompson CB. Tumor necrosis factor receptor-associated factors (TRAFs)–a family of adapter proteins that regulates life and death. Genes Dev (1998) 12:2821–30. doi: 10.1101/gad.12.18.2821
73. Rothe M, Sarma V, Dixit VM, Goeddel DV. TRAF2-mediated activation of NF-kappa B by TNF receptor 2 and CD40. Science (1995) 269:1424–7. doi: 10.1126/science.7544915
74. Schneider-Brachert W, Tchikov V, Neumeyer J, Jakob M, Winoto-Morbach S, Held-Feindt J, et al. Compartmentalization of TNF receptor 1 signaling: internalized TNF receptosomes as death signaling vesicles. Immunity (2004) 21:415–28. doi: 10.1016/j.immuni.2004.08.017
75. Brignole F, Pisella PJ, Goldschild M, De Saint Jean M, Goguel A, Baudouin C. Flow cytometric analysis of inflammatory markers in conjunctival epithelial cells of patients with dry eyes. Invest Ophthalmol Vis Sci. (2000) 41:1356–63.
76. Brignole F, Pisella PJ, De Saint Jean M, Goldschild M, Goguel A, Baudouin C. Flow cytometric analysis of inflammatory markers in KCS: 6-month treatment with topical cyclosporin A. Invest Ophthalmol Vis Sci. (2001) 42:90–5.
77. De Saint Jean M, Debbasch C, Rahmani M, Brignole F, Feldmann G, Warnet JM, et al. Fas- and interferon gamma-induced apoptosis in Chang conjunctival cells: further investigations. Invest Ophthalmol Vis Sci. (2000) 41:2531–43.
78. Strong B, Farley W, Stern ME, Pflugfelder SC. Topical cyclosporine inhibits conjunctival epithelial apoptosis in experimental murine keratoconjunctivitis sicca. Cornea (2005) 24:80–5. doi: 10.1097/01.ico.0000133994.22392.47
79. Adams JL, Badger AM, Kumar S, Lee JC. p38 MAP kinase: molecular target for the inhibition of pro-inflammatory cytokines. Prog Med Chem. (2001) 38:1–60. doi: 10.1016/S0079-6468(08)70091-2
80. Kotlyarov A, Neininger A, Schubert C, Eckert R, Birchmeier C, Volk HD, et al. MAPKAP kinase 2 is essential for LPS-induced TNF-alpha biosynthesis. Nat Cell Biol. (1999) 1:94–7. doi: 10.1038/10061
81. Ma X, Zou J, He L, Zhang Y. Dry eye management in a Sjogren's syndrome mouse model by inhibition of p38-MAPK pathway. Diagn Pathol. (2014) 9:5. doi: 10.1186/1746-1596-9-5
82. Luo L, Li DQ, Doshi A, Farley W, Corrales RM, Pflugfelder SC. Experimental dry eye stimulates production of inflammatory cytokines and MMP-9 and activates MAPK signaling pathways on the ocular surface. Invest Ophthalmol Vis Sci. (2004) 45:4293–301. doi: 10.1167/iovs.03-1145
83. Huang JF, Yafawi R, Zhang M, McDowell M, Rittenhouse KD, Sace F, et al. Immunomodulatory effect of the topical ophthalmic Janus kinase inhibitor tofacitinib (CP-690,550) in patients with dry eye disease. Ophthalmology (2012) 119:e43–50. doi: 10.1016/j.ophtha.2012.03.017
84. Lawrence DA. Transforming growth factor-beta: a general review. Eur Cytokine Netw. (1996) 7:363–74.
85. Zheng X, De Paiva CS, Rao K, Li DQ, Farley WJ, Stern M, et al. Evaluation of the transforming growth factor-beta activity in normal and dry eye human tears by CCL-185 cell bioassay. Cornea (2010) 29:1048–54. doi: 10.1097/ICO.0b013e3181cf98ff
86. Chotikavanich S, de Paiva CS Li de Q, Chen JJ, Bian F, Farley WJ, et al. Production and activity of matrix metalloproteinase-9 on the ocular surface increase in dysfunctional tear syndrome. Invest Ophthalmol Vis Sci. (2009) 50:3203–9. doi: 10.1167/iovs.08-2476
87. Choi W, Li Z, Oh HJ, Im SK, Lee SH, Park SH, et al. Expression of CCR5 and its ligands CCL3,−4, and−5 in the tear film and ocular surface of patients with dry eye disease. Curr Eye Res. (2012) 37:12–7. doi: 10.3109/02713683.2011.622852
88. Baudouin C, Liang H, Bremond-Gignac D, Hamard P, Hreiche R, Creuzot-Garcher C, et al. CCR 4 and CCR 5 expression in conjunctival specimens as differential markers of T(H)1/ T(H)2 in ocular surface disorders. J Allergy Clin Immunol. (2005) 116:614–9. doi: 10.1016/j.jaci.2005.05.033
89. Lee YJ, Scofield RH, Hyon JY, Yun PY, Lee HJ, Lee EY, et al. Salivary chemokine levels in patients with primary Sjogren's syndrome. Rheumatology (2010) 49:1747–52. doi: 10.1093/rheumatology/keq121
90. Murphy KJ, Cutter AR, Fang H, Postnikov YV, Bustin M, Hayes JJ. HMGN1 and 2 remodel core and linker histone tail domains within chromatin. Nucleic Acids Res. (2017) 45:9917–30. doi: 10.1093/nar/gkx579
91. Yang D, Postnikov YV, Li Y, Tewary P, de la Rosa G, Wei F, et al. High-mobility group nucleosome-binding protein 1 acts as an alarmin and is critical for lipopolysaccharide-induced immune responses. J Exp Med. (2012) 209:157–71. doi: 10.1084/jem.20101354
92. Smits K, Iannucci V, Stove V, Van Hauwe P, Naessens E, Meuwissen PJ, et al. Rho GTPase Cdc42 is essential for human T-cell development. Haematologica (2010) 95:367–75. doi: 10.3324/haematol.2009.006890
93. Coursey TG, de Paiva CS. Managing Sjogren's syndrome and non-Sjogren syndrome dry eye with anti-inflammatory therapy. Clin Ophthalmol. (2014) 8:1447–58. doi: 10.2147/OPTH.S35685
94. Bartlett JD, Keith MS, Sudharshan L, Snedecor SJ. Associations between signs and symptoms of dry eye disease: a systematic review. Clin Ophthalmol. (2015) 9:1719–30. doi: 10.2147/OPTH.S89700
95. Ramaswamy V, Remke M, Bouffet E, Faria CC, Perreault S, Cho YJ, et al. Recurrence patterns across medulloblastoma subgroups: an integrated clinical and molecular analysis. Lancet Oncol. (2013) 14:1200–7. doi: 10.1016/S1470-2045(13)70449-2
Keywords: HLA-DR, inflammatory targets, NanoString® assay, conjunctival imprints, dry eye disease
Citation: Kessal K, Liang H, Rabut G, Daull P, Garrigue J-S, Docquier M, Melik Parsadaniantz S, Baudouin C and Brignole-Baudouin F (2018) Conjunctival Inflammatory Gene Expression Profiling in Dry Eye Disease: Correlations With HLA-DRA and HLA-DRB1. Front. Immunol. 9:2271. doi: 10.3389/fimmu.2018.02271
Received: 12 June 2018; Accepted: 12 September 2018;
Published: 15 October 2018.
Edited by:
Kottarappat N. Dileepan, Kansas University of Medical Center Research Institute, United StatesReviewed by:
Yolanda Diebold, University of Valladolid, SpainGiuseppina Ruggiero, Università degli Studi di Napoli Federico II, Italy
Copyright © 2018 Kessal, Liang, Rabut, Daull, Garrigue, Docquier, Melik Parsadaniantz, Baudouin and Brignole-Baudouin. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Françoise Brignole-Baudouin, fbaudouin@15-20.fr