DOI: https://doi.org/10.21203/rs.3.rs-25725/v2
Background: Dry eye syndrome in which tear fluid quality or abnormality or kinetic abnormality is caused by many causes, resulting in decreased tear film stability. In recent years, more and more results from the studies indicate that miRNA alterations are involved in dry eye syndrome. And miRNA-146a-5p is a key regulator to regulate the inflammatory response. In this paper, we demonstrated whether miRNA-146a-5p could cure dry eye syndrome by regulating target genes based on network analysis.
Methods: In this paper, we collected the blood of patients with dry eye disease which served as a model group, the blood of healthy people was used as a control group. The expression of miRNA-146a-5p in the patients was detected by RT-PCR, the genes controlled by miRNA-146a-5p were predicted by Targetscan, miRDB, miRWalk and PicTar databases, the genes regulated by miRNA-146a-5p which is related to dry eye disease were selected by draw Venn diagram;
Results: The comparison of the general information between patients and healthy people was no significant difference, and it indicated that the two groups were comparable. The results of databases showed that IRAK1 was one of the target genes regulated by miRNA-146a-5p and it is related to dry eye disease. The expression of miRNA-146a-5p was negatively related to IRAK1 mRNA and protein. While IRAK1 had positive correlation with IL-6, TNF-α and CBP proteins.
Conclusion: These results emphasized that miRNA-146a-5p could inhibit the expression of IRAK1, IL-6, TNF-α and CBP so as to help reduce the inflammatory response in dry eye syndrome.
Dry eye syndrome, also known as keratoconjunctivitis, is a tear and ocular surface disease caused by a variety of factors, the main causes were decreased tear film stability and ocular surface damage induced by tear fluid and quantitative or kinetic abnormalities [1]. The disease is accompanied with eye dryness, redness, foreign body sensation and other ocular surface discomfort and visual impairment [2]. Dry eye syndrome occurs in women over 60 years of age, and its aetiology and clinical manifestations vary. The pathogenesis is still unclear. At present, the main clinical application of tear substitutes to relieve dry eye symptoms, but cannot effectively cure dry eye syndrome [3]. Inflammatory response, apoptosis, and changes in sex hormone levels are all associated with the development of dry eye syndrome, and inflammation is considered to be the most important factor in the pathogenesis of dry eye syndrome [4, 5].
Interleukin-1 receptor associated kinase 1 (IRAK1) is a serine-threonine kinase that mediates toll-like receptors (TLR) and IL-1 signalling pathways. These signalling pathways are critical for regulating immune responses and inflammatory processes [6].
MicroRNAs (miRNA), a class of non-coding RNA, regulated numerous physiological processes via regulating target gene expression negatively [7]. Excepted expression of microRNA in the dry eye syndrome that may be used as a hall marker. Research showed that microRNA-132 could attenuate LPS-induced inflammatory injury [8] and microRNA-146a is a key regulator to regulate the inflammatory response [9]. Therefore, in this paper we collected the blood of patients with dry eye syndrome served as a model, the blood of healthy people was served as a control group. The results about patients’ basic information showed that there was no significant difference and the two groups were comparable. The expression of miRNA-146a-5p in model group was decreased compared with the control group. The target genes which predicted by Targetscan, miRDB, miRWalk and PicTar databases proved that IRAK1 is one of the target genes regulated by miRNA-146a-5p and the miRNAs which were related to IRAK1 were visualized by cytoscape3.6.1; Luciferase reporter assay result showed that miRNA-146a-5p could regulate the expression of IRAK1 directly. The results of RT-PCR showed that miRNA-146a-5p was low-expression in model group compared with the control group, and the inhibitor reduced the miRNA-146a-5p successfully. The tendency of IRAK1 was negatively expressed with the miRNA-146a-5p trend. And the amount of TNF-α, IL-6, CBP was positively correlated with IRAK1. At last, western blot was used to detect the relative protein expression, the results indicate that miRNA-146a-5p could inhibit the expression of IRAK1 protein and the TNF-α, IL-6, CBP proteins were inhibited at the same time.
The present study was designed to study the possible mechanism of miRN-146a-3p in dry eye disease and provide a new method for the treatment of dry eye syndrome.
The patients
This experiment was carried out in the hospital in China from September 2016 to January 2019. 49 patients with dry eye disease and 53 healthy people were admitted in the study. The basic information was recorded and the study was approved by the hospital Ethics Committee and all patients had signed informed consent. The blood of patients with dry eye disease was collected as a model group, then 53 healthy people’s blood was collected as a control group. The expression of miRNA-146a-5p was detected by reverse transcriptase-polymerase chain reaction (RT-PCR).
Bioinformatics Analysis
The target genes of miRNA-146a-5p were predicted by Targetscan [10] (http://www.targetscan.org/vert_72/), miRDB [11] (http://mirdb.org/), miRWalk [12] (http://zmf.umm.uni-heidelberg.de/apps/zmf/mirwalk/), and PicTar [13] (https://pictar.mdc-berlin.de/), the results were admitted into draw Venn diagram [14] and the results belonged to the 4 databases were selected. Then we get the sequence of miRNA-146a-5p and the target gene and look for the combining site to identify the relationship between them. Then we look for the relative miRNAs of the target gene in dry eye disease and visualized by Cytoscape3.6.1 [15].
Cell Culture
The rats were sacrificed and soaked in alcohol with a volume fraction of 75% for 15 min. The rat lacrimal glands were removed with ophthalmic scissors and washed 3 times with phosphate buffered saline (PBS). The upper fascia and surrounding yellow adipose tissue were peeled off, and the dendritic blood vessels and fibrous connective tissue were removed. After rinsing in the original solution, the tissue was cut into 1~2 mm3 pieces with ophthalmic scissors. The prepared 2 g·L-1 type II collagenase application solution was added and shaken and digested for 25 min at 37°C in an electrothermal oven to obtain a gland cell mass. The culture solution was added to terminate the digestion, and the gland cell pellet was thoroughly blown into a single cell suspension. It was filtered through a 200-mesh nylon mesh and centrifuges at 800 r·min-1 for 5 min. The supernatant was added to a little D-Hank solution and centrifuged again at 800 r·min-1. The precipitate was taken, and the culture solution was added and pipetted into a single cell suspension, which was inoculated into a culture flask [16].
The cells were inoculated into a 50 mL plastic flask at 3 cm × 105 cm-2, and the lacrimal gland epithelial cells were purified by repeated adherence for 3 times (15 min to 20 min each), and cultured at 37°C in a volume fraction of 5% CO2 incubator. After 36 h, the first half was changed, and after 48 h, the whole amount was changed once. The liquid was changed once every 4 days. The first passage was performed after 10 days.
The concentration was 100 μmol / L H2O2 and the culture was continued for 60 min to induce cell death and recorded as a model group.
Luciferase reporter assay
Luciferase reporter assay was performed to identify the relationship between miRNA-146a-5p and IRAK1. In brief, cells at 80% confluence were co-transfected with wild-type or mutant IRAK1 3′-UTR reporters together with miRNA-146a-5p or negative control using Lipo 2000 (Invitrogen, Carlsbad, CA, USA). The plasmid (Promega, Madison, WI, USA) encoding luciferase was used to control for transfection efficiency. Cells were lysed 24 h after transfection and tested for luciferase activities using the Dual-Luciferase Reporter Assay System (Promega, Madison, WI, USA), according to the manufacturer’s instructions.
RT-PCR Analysis
The total RNA was isolated from mouse cells using TRIzol reagent (Invitrogen, Carlsbad, CA, USA) and converted to cDNA by OneScript Reverse Transcriptase cDNA Synthesis Kit (TaKaRa, Dalian, China). The bulge-loop TM miRNA reverse primer was used to replace Olige (dT). 25 μL Dream Taq PCR Master Mix (TaKaRa, Dalian, China), 1.5 μL primers (Ribobio, Guangzhou, China), 2 μL cDNA and 20 μL water nuclease free in amplification reaction mixture (50 μL), and the PCR condition were as follows: 95°C (2 min, a cycle), 95°C (30 s), 58°C (30 s), 72°C (1 min), 35 cycles in total. Finally, 72°C (10 min, a cycle) [17]. GADPH served as the control of APP and U6 snRNA (U6) served as control of miR-146a-5p (El Fatimy et al., 2018), the primer sequences were as follows: IRAK1: 5’-ATCAGGCTTTTTCCCAGGCT-3’; 5’-GCACACTATGAGAACTTCCAAGC-3’; TNF-α: 5’-ATAAGAGCAAGGCAGTGGG-3’; 5’-TCCAGCAGACTCAATACACA-3’; IL-6: 5’-AGCCAGAGTCCTTCAGAGAG-3’ and 5’-TCCTTAGCCACTCCTTCTGT-3’; miRNA-146a-5p: 5’-CTGCCGCTGAGAACTGAATT-3’; 5’-CAGAGCAGGGTCCGAGGTA-3’; GADPH: 5’-CCATGTTCGTCATGGGTGTGAACCA-3’; 5’-GCCAGTAGAGGCAGGGATGATGTTC-3’; calprotectin: 5’-CCGGATCCAC-TAAGCTGGAAGATCACCTGGAGG-3’; 5’-CCAAGCTTTACTCTTTGTGGATATCTAT-GTGGGCTG-3’.
Western Blot
Cells were lysed in radioimmuno precipitation assay buffers with the Protease Inhibitor Cocktail (Sigma-Aldrich, St. Louis, MO, USA), separated in sodium dodecyl sulphate polyacrylamide gels, and transferred to a polyvinylidene fluoride membrane. The membrane was incubated with anti-IRAK1, TNF-α, IL-6, CBP and anti-β-actin (Abcam, Cambridge, MA, USA) at 4°C overnight, followed by incubation with horseradish peroxidase-conjugated secondary antibodies for 1 h. Bands were visualized with electrochemiluminescence (ECL).
Statistical Analyses
Mean ± standard deviation was used to present the data. Statistical comparisons were carried out using the student’s t-test or one-way analysis of variance (ANOVA) followed by Tukey’s multiple comparison test.
General information comparison
The patient’s basic information was recorded before the patients were admitted into the hospital. The 49 patients with dry eye disease in the hospital were included in the model group, including 32 males and 17 females, and the average age of 37.4 ± 10.8 years. The body’s BMI value was 22.75 ± 3.14, while the control group was 53 healthy subjects who passed the physical examination in the hospital, including 20 males and 33 females, average age was 38.2±10.7, body BMI is also within the normal range. There was no statistical difference There was no statistical difference between the general information of the model combination control groups: they were comparable. See Table 1 for details.
MiRNA-146a-5p was low-expression in the patients with dry eye disease
To explore the expression of miRNA-146-5p in the patients with dry eye disease, the blood of the model and the control group one was selected, the expression of miRNA-146-A-5p was detected by RT-PCR. The result showed that miRNA-146a-5p had low-expression in model group compared with the control group. The difference between the two groups was statistically significant (Figure 1). It indicated that miRNA-146-5p may be the marker of dry eye disease.
IRAK1 Is the Target Gene Regulated by miRNA-146a-5p
To predict the target genes of miRNA-146a-5p, the databases were used. We can know that there are 7 genes regulated by miRNA-146a-5p determined by miRDB, miRWalk, PicTar, TargetScan databases (Figure 2A), including IRAK1, TRAF-6, NOVA1 and so on. Among them, IRAK1 is related to inflammatory response, while inflammatory response would lead to the dry eye disease. Therefore, we will focus on the specific mechanism of dry eye disease with miRNA-146a-5p and IRAK1 and explore the potential mechanism.
We explore the targeting relationship between miRNA-146a-5p and IRAK1 by establishing the network using cytoscape3.6.1. The network showed that there are numerous genes regulated by miRNA-146a-5p, and IRAK1 was one of them (Figure 2B).
IRAK1 Is the Target Gene Regulated by miRNA-146a-5p
To determine whether the inhibition of IRAK1 by miR-146a-5p occurred via these predicted miR-146a-5p binding sites, the combining site was mutated. Luciferase reporter assays indicated that the IRAK1 mutant 3ʹ-UTR interrupted miR-146a-5p-mediated repression, it indicated that miRNA-146a-5p could regulate the expression of IRAK1 directly (Figure 3).
MiRNA-146a-5p Inhibits Inflammatory Release by Targeting IRAK1 mRNA
Then we determined the expression of IRAK1 when miRNA-146a-5p with inhibition treatment (Figure 4A), we found that compared with the control group, the expression of miRNA-146a-5p was lower and IRAK1 higher at the same time in the model group. While the inhibitor group showed that the inhibition of miRNA-146a-5p would lead to the increase of IRAK1 mRNA, and when the expression of miRNA-146a-5p is rising, the IRAK1 mRNA would decrease at the same time. The relationship between miRNA-146a-5p and IRAK1 were negatively correlated. These results suggested that the highly conserved sequence of the IRAK1 3ʹ-UTR is the major miR-146a-5p binding site, and further confirmed that miR-146a-5p directly inhibits IRAK1(Figure 4B).
Then we detected the expression of IL-6, calprotectin and TNF-α (Figure 4A), the result showed that the expressions of IL-6, calprotectin and TNF-α were higher in the model group compared with the control group, and the expressions of IL-6, calprotectin and TNF-α in inhibitor groups were lower obviously (Figure 4B). It indicated that the up-regulating miRNA-146a-5p and targeting IRAK1 mRNA may inhibit inflammatory release.
At last, we detected the relationship of miRNA-146a-5p, IRAK1, calprotectin, IL-6 and TNF-α mRNA, the result showed that miRNA-146a-5p was negatively related with IRAK1, while the expression of IL-6, calprotectin, TNF-α had positive relation with IRAK1 and negatively related with miRNA-146a-5p (Figure 4C).
MiRNA-146a-5p attenuates inflammatory response by regulating TRAF-6 protein
In order to prove the effects of miRNA-146a-5p on the expression of IRAK1 protein, Western Blot was used. The IRAK1 protein was significantly increased in the model group compared with the control group while the expression of IRAK1 protein was the highest in the inhibitor group (Figure 5A), and the difference was statistically significant (P<0.01). MiRNA-146a-5p inhibitor attenuates the inhibitory effect of miR-146a-5p on IRAK1 protein expression.
At last, we detected the relationship of IRAK1, IL-6 and TNF-α proteins, the result showed that miRNA-146a-5p was negatively correlated to IRAK1, while the expression of calprotectin, IL-6 and TNF-α proteins had positive correlation with IRAK1 (Figure 5B).
Dry eye syndrome refers to a general term for a type of disease in which the composition and volume of tears or abnormalities in kinetics cause instability of the tear film, accompanied by eye discomfort such as dryness [18], visual fatigue [19], photophobia [20], and decreased vision [21]. In terms of classification, it is a kind of chalk disease, that is, there is no abnormality in appearance and the patient has obvious eye discomfort.
Dry eye syndrome is usually accompanied by inflammation [22]. Under the action of the body’s immune system, a certain number of lymphocytes infiltrate the ocular surface tissue and lacrimal gland, releasing a large number of inflammatory factors, causing the appearance of inflammation in the body, further affecting the tear secretion system of the human body, leading to pathological changes in the amount and composition of tear secretion [23]. In order to escape the attack from the lacrimal immune system, these lymphocytes secrete inflammatory factors, which also have the effect of affecting the secretion of normal glands; in addition, inflammatory factors can also exert effects on sympathetic and parasympathetic nerves, so that the sensory nerve function corresponding to the ocular surface decline, eventually destroying the integrity of the tear film [24].
Now,more and more research paid attention to miRNA in various diseases. Among them, the microRNA related to dry eye syndrome is a hot topic too [25]. And it could regulate numerous physiological processes via binding to the 3′ untranslatable region (3′-UTR) of their mRNA targets [26]. Up to now, many studies have demonstrated that miRNA-146a is an important regulator of inflammatory response [27], so its regulation of inflammatory response has an important impact on dry eye syndrome. However, whether miRNA-146a-5p could cure dry eye syndrome and its specific mechanism remains is still unclear. Therefore, in this paper, we collected the blood of patients with dry eye disease, which served as a model group, and the blood of healthy people served as a control group. We found that the comparison of the general information between patients and healthy people had no significant difference, and it indicated that the two groups were comparable. The expression of miRNA-146a-5p was lower in the model group compared with that in the control group. The target genes regulated by miRNA-146a-5p were predicted by Targetscan, miRDB, miRWalk and PicTar databases, the genes regulated by miRNA-146a-5p which are related with dry eye disease were selected by draw Venn diagram; the results of databases showed that IRAK1 was one of the target genes regulated by miRNA-146a-5p and it is related to dry eye disease. The results of luciferase reporter assay showed that miRNA-146a-5p could regulate the expression of IRAK1 directly. The expression of miRNA-146a-5p was negatively related to IRAK1 mRNA and protein. While IRAK1 had positive correlation with IL-6, TNF-α, CBP proteins.
These results emphasized that the up-regulation of miRNA-146a-5p could inhibit the expression of IRAK1, IL-6, TNF-α, CBP so as to help reduce the inflammatory response in dry eye syndrome.
CBP: Calmodulin Binding Peptide; IL-6: Interleukin- 6; IRAK1: Interleukin-1 receptor associated kinase 1; PBS: phosphate buffered saline; RT-PCR: reverse transcriptase-polymerase chain reaction; TLR: toll-like receptors; miRNA: MicroRNAs; TNF-α: tumor necrosis factor α;
Acknowledgements
Not applicable.
Authors’ contributions
Liang Yin has a major role in conception and design of work, performing surgical tasks, data acquisition, interpretation and analysis, drafting and review of the manuscript. Mingxue Zhang and Tiangeng He participated in data analysis, interpretation, drafting and final review of the manuscript. Song Chen participated in interpretation of data, drafting and revision of manuscript.
Funding
Not applicable.
Availability of data and materials
The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.
Ethics approval and consent to participate
The study was approved by the hospital Ethics Committee and all patients had signed informed consent.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no conflict of interest.