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Advances in Dermatology and Allergology/Postępy Dermatologii i Alergologii
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Original article

Combination of FLG mutations and SNPs of IL-17A and IL-19 influence on atopic dermatitis occurrence

Jolanta Klonowska
1
,
Jolanta Gleń
2
,
Roman J. Nowicki
2
,
Magdalena Trzeciak
2

  1. Independent Public Health Care Unit of Rypin, Rypin, Poland
  2. Department of Dermatology, Venereology and Allergology, Medical University of Gdansk, Gdansk, Poland
Adv Dermatol Allergol 2022; XXXIX (1): 200-208
Online publish date: 2021/04/16
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Introduction

Atopic dermatitis (AD) is a chronic, recurrent, heterogeneous and inflammatory skin disease, which involves severe pruritus. The number of people suffering from AD is relatively high. Epidemiological research demonstrates that 20% of children and 2–5% of adults suffer from AD [1–3]. Atopic dermatitis pathogenesis is multifactorial and consists of genetic, immunological, and environmental factors with a skin barrier defect and microbial dys­biosis. A fresh look on the AD pathophysiology has focused on the skin defect barrier and immune dysfunctions. Skin barrier defect includes disorders of cornified envelope proteins, intracellular lipids of stratum corneum abnormalities, antimicrobial peptides, tight junctions and proteases dysfunctions. Filaggrin is a major structural protein in the stratum corneum of the epidermis. The FLG gene is located in the epidermal differentiation complex on chromosome 1q21. The null mutations of the FLG gene observed in up to 50% of AD patients are known as key players in AD pathogenesis associated with the severe AD course, early onset, elevated IgE and concomitant asthma [4–6]. Skin barrier defect facilitates allergen and microbiome penetration and increases inflammation.
It is known that immune aberrations in AD concern Th2 lymphocyte disorders and the cytokines released by them, interleukin (IL)-4, IL-5, IL-13, leading to increased IgE processing, exacerbation of the skin inflammation and aggravation of the epidermal barrier defect [7]. Apart from the Th2-dependent response, lymphocytes Th17 and Th22 affect the inflammation of the skin in patients with atopic dermatitis releasing, among others, such cytokines as IL-17, IL-19, and IL-22 [8, 9]. It is widely known that T helper 2 (Th2) and Th22 cells activation is the principal initiator of acute AD pathology, with the emergence of Th1 and Th17/IL-23 pathway activation marking the transition to a chronic state [10]. Ethnic differences in immunologic characteristics are observed.
The IL-17 family of cytokines is a group of homologous proteins: IL-17A and IL-17B to IL-17F [11]. Interleukin-17A, a distinctive cytokine, is produced not only by the T helper 17 cells (Th17 cells) but also by other cells such as cytotoxic CD8+ T cells (Tc17 cells), invariant natural killer T cells (iNKT cells), innate lymphoid cells (ILC), B cells, neutrophils, and other non-hematopoietic cells. All of these lymphocytes express the retinoic acid receptor-related orphan nuclear receptor C (RORC). During development, Th17 cells show flexible or plastic features distinct from those of Th1 and Th2 cells [12]. Genes for IL-17A are located on chromosome 6p12 [13]. Interleukin-17A is a secreted pro-inflammatory cytokine that acts on/affects a variety of cells, e.g. fibroblasts, epithelial cells, endothelial cells, and monocytes to induce the production of other cytokines, including IL-6, tumour necrosis factor- (TNF-), granulocyte-macrophage colony-stimulating-factor (GMCSF), granulocyte colony-stimulating-factor (GCSF), chemokines (CXCL1, CXCL2, CXCL5, and CXCL8), antimicrobial peptides (defensins) and matrix metalloproteinases (MMP1, MMP3, and MMP13) [14, 15]. The effect of this process is the recruitment, activation and migration of neutrophils and myeloid cells, and also angiogenesis and tissue destruction.
Receptor A IL-17 (IL-17RA) belongs to the IL-17 family of receptors, which consists of five members (IL-17RA, IL-17RB, IL-17RC, IL-RD, IL-RE). They share sequence homology but IL-17RA is ubiquitously expressed on a wide range of tissues and cell types. Receptor IL-17 RA after stimulating IL-17 initiates and activates downstream signalling pathways of pro-inflammatory molecules production. However, IL-17RA stimulation is insufficient, because IL-17 signals must be transmitted by a heterodimeric receptor complex composed of IL-17RA and IL-17RC [16–18]. The IL-17A may affect the pathology of AD by different means. The murine model of AD lacks IL-17 attenuated skin inflammation, IgE and IL-4 production [19]. Furthermore, IL-17A induced the differentiation of Th2 producing IL-4, confirming that IL-17 also modulates Th2 mediated immune response [19]. Interleukin-17A exacerbates the phases of AD by producing the downstream chemokines such as CXCL1, CXCL2, CXCL10, and CCL2 through the inhibition of EGFR (epidermal growth factor receptor) signalling pathway [20]. In the acute phase of AD, the level of IgE is increased. When cells were stimulated by IL-17A, B cells show increased survival, proliferation, and differentiation into plasma cells [21]. Research has confirmed that IL-17A provoked the IgE production by B cells in humans [22].
Interleukin-17A enhances epidermal TJ barrier integrity [23]. Tight junctions are transmembrane proteins important in keratinocyte adhesion. Atopic dermatitis patients demonstrate proteins of tight junctions, particularly in filaggrin mutations [24]. Interleukin-19 (IL-19) is a pro-inflammatory cytokine that stimulates the production of type 2 T-helper cells (Th2) [25]. Interleukin-19 belongs to the IL-10 family of cytokines (including IL-20, 22, 24, and 26). Its gene is located on chromosome 1q32 [26]. The human IL-19 gene is composed of seven exons and six introns and is encoded by exons 3–7. The IL-19 subfamily has 3 members, IL-19, IL-20 and IL-24 of a similar structure. The IL-19 receptor consists of IL-20R1 and IL-20R2. A heterodimer complex mediates its signal transduction and is an activator of transcription (STAT) 3 [27, 28]. Vital cellular sources of IL-19 are monocytes [29] and keratinocytes [30]. In monocytes, lipopolysaccharide (LPS) and granulocyte macrophage colony stimulating factor (GM-CSF) upregulate IL-19 expression. Interleukin-19 stimulates IL-6 and tumour necrosis factor (TNF) expression and activates monocyte apoptosis and the production of reactive oxygen species (ROS) [31]. Activities and functions of IL-19 and IL-10 are different. IL-10 inhibits production of TNF-, IL-6, cell apoptosis, and ROS production, in contrast to IL-19. Monocytes may use the production of TNF- to cause apoptosis in other cells as a defence mechanism against infection after receiving a signal from IL-19, which means a paracrine and not an autocrine effect. In turn, keratinocytes express IL-19 receptors suggesting that IL-19 may act in an autocrine manner [32]. Still little is known about the molecular mechanism of IL-19 signalling in the pathogenesis of AD; IL-19 which was originally associated with the development of type 2 helper T cell-responses and it is also associated with the development of type 1 helper T cell-responses [33]. It has been proved that IL-19 increases Th2 cytokine expression in activated T cells [34]. Oka et al. demonstrated that IL-19 protein levels in sera of AD patients were significantly elevated compared with normal controls. Serum IL-19 levels increased according to AD severity. Konrad et al. demonstrated that in atopic dermatitis, IL-19 was significantly elevated, correlated with EASI scores, and lowered with skin improvement [35]. In vitro, IL-19 is strongly expressed in AD lesional skin under the influence of IL-17A, because it is up-regulated in keratinocytes by IL-17A and IL-4. It indicates that IL-19 may be important for bridging Th17 to Th2 in AD [25]. In our paper we have decided to examine the influence of the occurrence of polymorphism rs2275913 in the promoter region of the IL-17A gene and rs22431188 in the promoter region of IL-19 with AD alone and while combining 2282del4 FLG gene mutations. Concerning the complex character of AD, searching for prognostic panels in AD is needed.

Material and methods



Material

239 AD patients were analysed (140 women and 99 men) who were the patients of the Department of Dermatology, Venerology and Allergology, Medical University of Gdansk. Patients were recognised as suffering from AD according to valid criteria proposed by Hanifin and Rajka [60]. The AD patients taking immunosuppressive treatment or other immunotherapy (UV phototherapy, cyclosporine A, oral corticoid, breast feeding and pregnant women, patients with inflammatory autoimmune and cancer diseases were excluded from the study. The control group was composed of 170 healthy persons (83 women and 87 men) with a negative individual and family interview for atopic illnesses. The groups were not ethnically different.

Methods

This study was performed to assess a potential association of AD with IL-17A, IL-19 genes and 2282del4 and R510X FLG mutation single nucleotide polymorphisms (SNPs). The analysis of polymorphic variants of IL-17A gene rs22431188 and IL-19 gene rs2275913 and 2282del4 and R510X FLG mutations was performed by the amplification – the polymerase chain reaction method (ARMS-PCR) using designed sequence-specific primers (PCR-SSP). All test samples were evaluated together with the growth hormone internal amplification control 1 (GH1). Genomic DNA was isolated from peripheral blood samples using Blood DNA Prep Plus (A&A Biotechnology, Gdansk, Poland). Serum total IgE levels were measured by the fluoroimmunoenzyme assay using the Uni-CAP 100 System (Phadia, Uppsala, Sweden). The cut-off point for serum IgE was 100 kU/l. All analyses were performed according to the manufacturer’s protocols. Atopic dermatitis severity was assessed using the SCORAD scale (severe (SCORAD > 50, moderate (SCORAD 25–50, and mild (SCORAD < 25) [61]. The assessment of pruritus severity was performed using the visual analogue scale (VAS) (< 3 mild pruritus, 3-6.9 – moderate pruritus, 7-8.9 – severe and 9-10 – very severe) [62]. The study was approved by the local ethics committee of the Medical University of Gdansk (no. NKBBN/ 113/2019).

Statistical analysis

Data were calculated for measurable variables: arithmetic mean (x–) and median (Me) and standard deviation (SD), coefficient of variation (v%). Minimum (min) and maximum (max) values were also given. Before making a comparison of averages in the examined groups, the coherence of analysed measurable variables with normal division was checked by means of Shapiro-Wilk test. When comparing averages in two groups, Mann-Whitney test was used, and in a few subgroups – ANOVA Kruskal-Wallis test. In order to compare frequencies, different types of variables in examined groups and subgroups were used. To check the reliance between qualitative variables, unreliance test 2 was performed. In the case of a theoretical numerical amount lower than 5, Yates alteration was taken into consideration. In case of a very small numerical amount in the chart (< 3), the Fisher’s precise test was used. The odds ratio (OR) was calculated and reliance divisions were determined for them. The statistical significance of all tests is 0.05. Statistical analysis was made by means of statistical programme Statistica 10.0 StatSoft® [63].

Results

Atopic dermatitis features

The average age of AD patients was 25.5 years. The average age of controls was 27.1 years. Severity of AD was as follows: severe (SCORAD > 50, n = 66), moderate (SCORAD 25–50, n = 50), and mild (SCORAD < 25, n = 21). The average SCORAD score was 52.0 (48.3–52.7) CI 95%. Assessment of pruritus severity revealed: mild pruritus 20.7%, moderate pruritus 37.9%, severe 30.8% and very severe 10.6%. The average pruritus was 5.65 (5.09–6.21; CI 95%). Genotyping for IL-17A gene polymorphism rs2275913 and IL-19 polymorphism rs22431188 Distribution of the genotypes and alleles for IL-17A and IL-19 was consistent with HWE (Hardy-Weinberg equilibrium) in patient and control groups and it is presented in Table 1. We found three genotypes for IL-17A (G/G, G/A and A/A) and for IL-19 (C/C, C/A, A/A) in both groups. The distribution frequency of polymorphisms and alleles did not show any statistical significance (p > 0.05) (Table 1). We found no evidence of any effect of IL-17A and IL-19 on the occurrence of AD in the Polish population (p > 0.05).
The association between rs2275913/17a and rs22431188/IL-19 polymorphisms with IgE levels, SCORAD score, pruritus severity and coexisting asthma We found no association between the presence of the SNPs of rs2275913/17a and rs22431188/IL-19 and IgE levels (p > 0.05) (rs2275913/17a: 2 = 0.693; p = 0.707 and rs22431188/IL-19: 2 = 1.074; p = 0.584, respectively (Figure 1 A, B). No evidence was found of a link between rs2275913/17a and rs22431188/IL-19 polymorphisms with the AD intensification severity measured by SCORAD: mild, mode­rate and severe (p > 0.05) (Figure 1 A, B; rs2275913/17a: 2 = 0.682, p = 0.954; rs22431188/IL-19: 2 = 3.367, p = 0.498, respectively). In both rs2275913/17a and rs22431188/IL-19 polymorphisms, no significant relationship in average pruritus results was revealed nor the frequency of occurrence of mild, moderate, severe and very severe pruritus (p > 0.05) (Figure 1 A, B).
No significant statistical correlation between asthma and polymorphisms rs2275913/17a (p > 0.05; 2 = 1.436; p = 0.488) and rs22431188/IL-19 (p > 0.05; 2 = 0.539; p = 0.764) was found. Association between rs2275913/IL-17A and rs22431188/IL-19 polymorphisms and concomitant 2282del4 FLG mutation and the frequency of AD The connection of IL-17a-rs2275913/17a and rs22431188/IL-19 polymorphisms with 2282del4 FLG mutation gene was examined (Table 2). There has been a significant statistical link of AD occurrence in patients with G/G IL-17A polymorphism with 2228del4 FLG mutation revealed (p = 0.0266, 2 = 4.917). It turned out that in the group of patients with the G/G polymorphism, the frequency of AD was not statistically higher than in controls, however when we combine the G/G polymorphism and FLG mutation, such a combination was much more frequent among AD patients compared to the control group (92.3% vs. 7.7%; OR = 9.1; confidence interval is 1.16–71.4). This means that among the study subjects having the polymorphism and FLG mutation, AD occurs 9 times more often than in the study subjects with the GG polymorphism only.
Similar statistical difference in the AD occurrence was noticed in the case of patients with the G/A polymorphism of IL-17a and FLG mutation. It turned out that in the group of the G/A genotype in IL-17a (rs2275913) the frequency of AD was much smaller than in the group of patients with the G/A polymorphism and FLG mutation (0% vs. 100.0%; 2 = 5.707; p = 0.0169). In the group of the C/C IL-19 polymorphism, the frequency of AD was much smaller than in the group of patients with the CC polymorphism and FLG mutation present. A significant statistical difference was noted (0% vs. 100.0%; p < 0.01; 2 = 10.490, p = 0.0012).
In turn, there has been a non-significant but close to statistical significance of AD occurrence revealed in patients with the C/A IL-19 polymorphism. It turned out that in the group of patients with the C/A polymorphism, the frequency of AD was much lower than in the study group with the C/A polymorphism and FLG gene mutation (10% and 90.0%; OR = 6.0). The reliance division is 0.74-49.0 (p = 0.055). This means that among the study subjects having the C/A polymorphism and FLG mutation, AD occurs 6 times more often than in the study subjects with the polymorphism only. As it can be seen, among 10 patients with a FLG mutation and C/A IL-19 polymorphism, 9 suffered from AD and one was from the control group. The frequency of FLG rs2282del4 and R501X mutation was examined. A statistically significant correlation was found in the results distribution for FLG rs2282del4 mutation in the patient and control group (p < 0.05; 2 = 7.699; p = 0.0213, OR = 10.7; CI: 1.18–69.9). This section may be divided by subheadings. It should provide a concise and precise description and interpretation of the experimental results as well as the experimental conclusions that can be drawn.

Discussion

Atopic dermatitis often coexists with other atopic diseases such as conjunctivitis, allergic rhinitis or asthma. It is a chronic, recurrent, heterogeneous and inflammatory skin disease, which involves severe pruritus. Atopic dermatitis pathogenesis is multifactorial and consists of genetic, immunological and environmental factors with the skin barrier defect and microbial dysbiosis. Some part of AD vulnerability was identified. The FLG mutation is a risk factor for AD in the European population. It exists in one tenth of the Northern European population but only 1% of Africans [36, 37]. Our results confirm a significant FLG mutation contribution to AD pathogenesis.
Traditionally, it is believed that Th cells differentiate into Th1 and Th2 subgroups. Atopic dermatitis is characterized by a strong Th2-dependent immune response. However, lymphocytes Th1, Th22, Th17 / IL-23 have an influence on the inflammation process. IL-17 is produced by subgroups of T CD4 + lymphocytes – Th17 cells. The Th17 cells are vital to the adaptive immune response against bacterial and fungal infections, and also contribute to the pathogenesis of several inflammatory diseases. The pathogenetic role of Th17 and IL-17 cells in different autoimmune and inflammatory processes was observed [38–40]. IL-17A which is produced by type 17 helper T cells has been related to neutrophilic inflammation in asthma [41]. Thus, numerous research in different populations was aimed to examine the connection between the IL-17A polymorphism not only with AD, but also with asthma. In Portuguese adults, a connection between polymorphisms of the IL-17A (rs2275913) gene with rhinitis and/or asthma was evaluated. IL-17A rs2275913 AA genotype was less associated with asthma than with rhinitis [39]. The research conducted in Saudi Arabia showed that AG heterozygotes of rs17880588 in IL-17A were significantly more common in the control group than among asthma patients. For any of the other SNPs examined (rs17878530), no significant associations were observed in this population. Hence, the results revealed an association between rs17880588 (G/A) and protection from asthma in the Saudi population [42]. Research results in the Chinese population preliminarily indicate that the IL-17A genotype AT (rs7758579 – rs11966760) was thought to be a risk of allergy rhinitis (AR) – asthma (A). Moreover, SNPs and some intergenic variants have a potential association with AR and comorbid asthma [43]. Maalmi results suggested that SNPs in IL-17A and IL-17F confer susceptibility to childhood asthma in Tunisia [44]. However, Wang et al. failed to find an association between IL-17A rs2275913 polymorphism and asthma risk [45]. The variant genotype of IL-17A rs2275913 polymorphism GA or AA was a significant protective factor for asthma in schoolchildren aged 7 to 13 years in the study group with bronchiolitis in early infancy [46].
In the meta-analysis assessing the effect of IL-17A rs2275913 polymorphism on the risk of asthma, ten studies with a total of 5016 participants (2510 asthma cases and 2506 controls) were ultimately identified. The results of this meta-analysis indicate that the G allele of rs2275913 in IL-17A is a protective factor for the development of asthma. The G allele of rs2275913 in IL-17A is significantly associated with a reduced risk of asthma in children and Asians, in subgroup analysis by age and ethnicity [47]. Narbutt et al. found that the A/A genotype in IL-17A predisposed to increased AD severity and coexistence of AD and asthma [48]. However, they found no evidence of any effect of IL-17A on the occurrence of AD in the Polish population, which was consistent with our results. However, we found no correlation between the AD severity and asthma coexistence combined with examined polymorphisms IL-17A. This may be a result of different ethnic roots in these two parts of Poland. In our study, patients were mainly from northern Poland rather than central Poland and the number of AD patients examined in our group was bigger.
Interleukin-19 is primarily made by monocytes, where its expression can be induced by LPS, IL-4, and GM-CSF. IL-19 signals through a receptor complex composed of the IL-20R1 as well as IL-20R2 chains and activates monocytes in an autocrine and paracrine way to release cytokines IL-6, TNF-, and numerous ROSs. Interleukin-19 stimulates the production of Type 2 T-helper cells (Th2). It is thought that IL-19 is crucial for bridging Th17 to Th2 pathway. What is also important, they put attention to the possible influence of FLG mutation coexisting with certain IL-17 and IL-19 polymorphisms on the AD occurrence. The combination of FLG mutations and SNPs of IL-17A and IL-19 influences the frequency of AD occurrence. Expression of epidermal FLG is down regulated by cytokines IL-4, IL-13, IL-17A, IL-22, IL-25, IL-31, TNF- in AD patients [49–55].
Filaggrin expression at the mRNA level is directly and indirectly downregulated by IL-17A by affecting profilaggrin mRNA expression, production of functional filaggrin monomers and their degradation at the level of enzymatic processing. Keratinocytes stimulation with IL-17A alters many cellular processes that can affect the barrier function of the skin, with a special influence on the response to inflammation, epidermal differentiation, formation of cornified envelope, and stress as well as chemotaxis [50]. It is also worth reminding the study by Teunussen et al. which reported that IL-17A upregulates both HLA-DR molecules and ICAM-1 in keratinocytes. It contributes to the formation of a functional immunological synapse and enhancement of antigen presenting function of these cells [56].
Research on polymorphism genes of IL-19 is not common. In the north Indian population, IL-19 –35402 C/C (rs2243158) genotype was associated with an increased risk of psoriasis. Researchers did not find any significant association of IL-19 –42232 C/A (rs2243188), –38386 T/C (rs2073186) with psoriasis [57]. In turn, the study on the European population reveals that there is no significant difference of IL-19 gene SNPs in psoriasis patients and controls [58]. Interleukin-19 belongs to the IL-10 family of cytokines and its gene is located on chromosome 1q32. Interleukin-10 –1082 A/G, –819 T/C and –592 A/C polymorphisms were not strongly connected with the susceptibility to atopic dermatitis [59]. There might be a phenomenon existing in genetics of the additive influence of coexistence of 2282del4 FLG mutations with the polymorphism in promotor region rs2275913 of IL-17A and rs22431188 of IL-19 gene SNPs on the development of AD. It is claimed that patients with a 2282del4 FLG mutation who have certain polymorphism variants are at a greater risk of an illness occurrence than patients with polymorphisms only and without FLG mutation.
Limitations of the study may result from the fact that the group was ethnically limited and there could be some gene-environment interaction. Patients were heterogeneous as far as AD severity and its course are concerned. The majority had a moderate and severe course, which may influence the results. Moreover, the number of patients taking part in the research was also limited. These discrepancies could be due to differences in patient demographics, sample size, environmental factors, and genetic background, all of which can affect association studies. Various research results may come from choosing a different group of patients so further cytokines research is vital. Our research results, on the contrary, showed the correlation of AD occurrence in the case of polymorphisms IL-17A and IL-19 with coexisting FLG mutation. It may indicate an additive influence of immune and genetic disorders on AD pathogenesis. We are aware that both IL-17A and IL-19 play an essential role in pathophysiology of AD. Research continuation in the future with even better patient choice will not only provide better understanding of the AD mechanism but also contribute to the therapy individualization. It is a vital direction in the future research.

Conclusions

Our research gives new insights into the complex AD pathophysiology on mutual interaction of 2282del4 FLG mutations and SNPs of IL-17A (rs2275913) and IL-19 (rs22431188) which have an influence on AD occurrence. It seems that in this complex disease, not only one genetic marker, but rather panels are useful for diagnostics and prediction.

Acknowledgments

Grant no. 02-0066/07 has been received from the Polish Ministry of Science and Higher Education.

Conflict of interest

The authors declare no conflict of interest.

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