Association of PSORS1C3, CARD14 and TLR4 genotypes and haplotypes with psoriasis susceptibility

Linh, Nguyen Thi Thuy; Giang, Nguyen Hoang; Lien, Nguyen Thi Kim; Trang, Bui Kieu; Trang, Do Thi; Ngoc, Nguyen Thy; Nghia, Vu Xuan; My, Le Tra; Mao, Can Van; Hoang, Nguyen Huy; Xuan, Nguyen Thi

doi:10.1590/1678-4685-GMB-2022-0099

Abstract

Psoriasis is a common chronic, immune-mediated inflammatory disease of the skin. PSORS1C3 is a non-protein coding gene, of which the RNA transcript is found in psoriatic patients. CARD14 is mainly expressed in epidermal keratinocytes. TLR4 is a transmembrane protein to recognize microbial antigens. Our study aimed to assess the relationship among PSORS1C3, CARD14 and TLR4 polymorphisms, inflammatory expression and psoriasis susceptibility. To the end, 71 patients with psoriasis and 46 healthy individuals with the well-characterized clinical profiles were enrolled. Gene polymorphisms were determined by Sanger DNA sequencing and secretion of cytokines by ELISA. As a result, genetic analysis of PSORS1C3 gene identified nine SNPs and three haplotype blocks. Sequencing of the CARD14 gene determined eight SNPs and one haplotype block. Sequencing of TLR4 gene identified nine SNPs, in which a SNP rs1018673641 was found to exert deleterious effect. The linkage disequilibrium analysis showed that seven variants in PSORS1C3 gene and three SNPs in CARD14 gene were in tightly linked. More importantly, a significant association between IL-6 level and rs1018673641 AT genotype in TLR4 gene was detected in psoriatic patients. In conclusion, the PSORS1C3, CARD14 and TLR4 polymorphisms and haplotypes may be correlated with risk of suffering psoriasis and the IL-6-mediated chronic inflammation in psoriasis could be partially regulated by the TLR4 functional variant.

Keywords:
CARD14 ; polymorphism; PSORS1C3 ; psoriasis; TLR4

Introduction

Psoriasis is a common chronic, immune-mediated inflammatory skin disease, affecting 2-3% of the population (Afonina et al., 2021Afonina IS, Van Nuffel E and Beyaert R (2021) Immune responses and therapeutic options in psoriasis. Cell Mol Life Sci 78: 2709-2727.). The typical clinical manifestation of psoriasis includes widely distributed scaly erythema or plaques, which are commonly located on the scalp, elbows, knees and lumbar area (Parisi et al., 2013Parisi R, Symmons DP, Griffiths CE, Ashcroft DM; Identification and Management of Psoriasis and Associated ComorbidiTy (IMPACT) project team (2013) Global epidemiology of psoriasis: A systematic review of incidence and prevalence. J Invest Dermatol 133:377-385.). There are five different types of psoriasis, in which plaque psoriasis is the most common form of the disease and accounts for approximately 90% of the cases (Griffiths et al., 2007Griffiths CE and Barker JN (2007) Pathogenesis and clinical features of psoriasis. Lancet 370:263-271.). Psoriasis is associated with systemic inflammation caused by the recruitment of inflammatory cells, including macrophages, T cells and neutrophils into the epidermis of psoriatic skin (Takeshita et al., 2017Takeshita J, Grewal S, Langan SM, Mehta NN, Ogdie A, Van Voorhees AS and Gelfand JM (2017) Psoriasis and comorbid diseases: Implications for management. J Am Acad Dermatol 76:393-403.; Ren et al., 2020Ren F, Zhang M, Zhang C and Sang H (2020) Psoriasis-like inflammation induced renal dysfunction through the TLR/NF-kappaB signal pathway. Biomed Res Int 2020: 3535264.). Individuals with psoriasis are at an increased risk of developing other serious diseases, such as hypertension, diabetes, liver and kidney disease, and atherosclerosis (Takeshita et al., 2017Takeshita J, Grewal S, Langan SM, Mehta NN, Ogdie A, Van Voorhees AS and Gelfand JM (2017) Psoriasis and comorbid diseases: Implications for management. J Am Acad Dermatol 76:393-403.). During the inflammatory process, activation of Th1 and Th17 cells via a nuclear factor kappa-light-chain-enhancer of activated B (NF-κB) pathway is triggered by mature plasmacytoid and myeloid dendritic cells, which are migrated into the skin-draining lymph nodes and produce psoriasis relevant mediators of inflammation (Wagner et al., 2010Wagner EF, Schonthaler HB, Guinea-Viniegra J and Tschachler E (2010) Psoriasis: what we have learned from mouse models. Nat Rev Rheumatol 6:704-714.; Mease, 2015Mease PJ (2015) Inhibition of interleukin-17, interleukin-23 and the TH17 cell pathway in the treatment of psoriatic arthritis and psoriasis. Curr Opin Rheumatol 27:127-133.; Tang et al., 2021Tang H, Guo Z, Tang X, Gao J, Wang W, Huang H, Zheng X, Cheng H, Sheng Y and Sun L (2021) MST1 modulates Th17 activation in psoriasis via regulating TLR4-NF-kappaB pathway. Hum Cell 34:28-36.).

Genetic investigations have shown that psoriatic patients have diverse gene polymorphisms related to skin barrier function (van den Bogaard et al., 2014van den Bogaard EH, Tjabringa GS, Joosten I, Vonk-Bergers M, van Rijssen E, Tijssen HJ, Erkens M, Schalkwijk J and Koenen H (2014) Crosstalk between keratinocytes and T cells in a 3D microenvironment: a model to study inflammatory skin diseases. J Invest Dermatol 134:719-727.). More than 30 single nucleotide polymorphisms (SNPs) have been associated with the risk of developing psoriasis. Among them, the psoriasis susceptibility 1 (PSORS1) gene is the major susceptibility locus for psoriasis (Mohd Affandi et al., 2018Mohd Affandi A, Khan I and Ngah Saaya N (2018) Epidemiology and clinical features of adult patients with psoriasis in Malaysia: 10-year review from the Malaysian Psoriasis Registry (2007-2016). Dermatol Res Pract 2018:4371471.). PSORS1 is located within the major histocompatibility complex (MHC) on chromosome 6p21.3 (Mohd Affandi et al., 2018Mohd Affandi A, Khan I and Ngah Saaya N (2018) Epidemiology and clinical features of adult patients with psoriasis in Malaysia: 10-year review from the Malaysian Psoriasis Registry (2007-2016). Dermatol Res Pract 2018:4371471.), in which the non-protein coding gene PSORS1C3 is an established susceptibility gene for psoriasis and its RNA transcript is found both in psoriatic patients and control individuals (Holm et al., 2005Holm SJ, Sanchez F, Carlen LM, Mallbris L, Stahle M and O’Brien KP (2005) HLA-Cw*0602 associates more strongly to psoriasis in the Swedish population than variants of the novel 6p21.3 gene PSORS1C3. Acta Derm Venereol 85:2-8.). The -26C and +246A alleles in the PSORS1C3 gene are strongly associated with psoriasis in the Swedish, but not in Chinese population (Holm et al., 2005Holm SJ, Sanchez F, Carlen LM, Mallbris L, Stahle M and O’Brien KP (2005) HLA-Cw*0602 associates more strongly to psoriasis in the Swedish population than variants of the novel 6p21.3 gene PSORS1C3. Acta Derm Venereol 85:2-8.). Although the association of PSORS1C3 polymorphisms with psoriasis has been widely studied (Holm et al., 2005Holm SJ, Sanchez F, Carlen LM, Mallbris L, Stahle M and O’Brien KP (2005) HLA-Cw*0602 associates more strongly to psoriasis in the Swedish population than variants of the novel 6p21.3 gene PSORS1C3. Acta Derm Venereol 85:2-8.; Chang et al., 2006Chang YT, Chou CT, Shiao YM, Lin MW, Yu CW, Chen CC, Huang CH, Lee DD, Liu HN, Wang WJ et al. (2006) Psoriasis vulgaris in Chinese individuals is associated with PSORS1C3 and CDSN genes. Br J Dermatol 155:663-669.), the regulatory role of PSORS1C3 on immune cell function is little known.

Immunogenomics studies have indicated that constitutive activation of toll-like receptors (TLRs) is induced by their abnormal mRNA expression or causal mutations (Smith et al., 2016Smith RL, Hebert HL, Massey J, Bowes J, Marzo-Ortega H, Ho P, McHugh NJ, Worthington J, Barton A, Griffiths CE et al. (2016) Association of Toll-like receptor 4 (TLR4) with chronic plaque type psoriasis and psoriatic arthritis. Arch Dermatol Res 308:201-205.; Shao et al., 2019Shao S, Fang H, Dang E, Xue K, Zhang J, Li B, Qiao H, Cao T, Zhuang Y, Shen S et al. (2019) Neutrophil extracellular traps promote inflammatory responses in psoriasis via activating epidermal TLR4/IL-36R crosstalk. Front Immunol 10:746.). Each of the TLR subtypes has its own specific recognition pattern upon ligand engagement, in which TLR4 is the transmembrane protein expressed on antigen-presenting cells to recognize microbial antigens and contributes as the initiator of inflammatory response in innate immunity (Traks et al., 2015Traks T, Keermann M, Karelson M, Ratsep R, Reimann E, Silm H, Vasar E, Koks S and Kingo K (2015) Polymorphisms in Toll-like receptor genes are associated with vitiligo. Front Genet6:278.). A recent study reveals that in patients with psoriasis, activation of the NF-κB signaling is triggered by TLR4 (Tang et al., 2021Tang H, Guo Z, Tang X, Gao J, Wang W, Huang H, Zheng X, Cheng H, Sheng Y and Sun L (2021) MST1 modulates Th17 activation in psoriasis via regulating TLR4-NF-kappaB pathway. Hum Cell 34:28-36.) to exert chronic inflammatory condition (Takeshita et al., 2017Takeshita J, Grewal S, Langan SM, Mehta NN, Ogdie A, Van Voorhees AS and Gelfand JM (2017) Psoriasis and comorbid diseases: Implications for management. J Am Acad Dermatol 76:393-403.). The release of inflammatory cytokines such as TNF-α/IL-23/IL-17 in psoriatic patients is involved in excessive proliferation and aberrant differentiation of keratinocytes (Mease, 2015Mease PJ (2015) Inhibition of interleukin-17, interleukin-23 and the TH17 cell pathway in the treatment of psoriatic arthritis and psoriasis. Curr Opin Rheumatol 27:127-133.; Takeshita et al., 2017Takeshita J, Grewal S, Langan SM, Mehta NN, Ogdie A, Van Voorhees AS and Gelfand JM (2017) Psoriasis and comorbid diseases: Implications for management. J Am Acad Dermatol 76:393-403.). The serum level of the cytokines is correlated with the clinical severity and pathogenesis of psoriasis (Cai et al., 2019Cai Y, Xue F, Quan C, Qu M, Liu N, Zhang Y, Fleming C, Hu X, Zhang HG, Weichselbaum R et al. (2019) A critical role of the IL-1beta-IL-1R signaling pathway in skin inflammation and psoriasis pathogenesis. J Invest Dermatol 139:146-156.). Polymorphisms within the TLR4 gene have been associated with a number of immune-mediated inflammatory diseases, such as psoriasis (Smith et al., 2016Smith RL, Hebert HL, Massey J, Bowes J, Marzo-Ortega H, Ho P, McHugh NJ, Worthington J, Barton A, Griffiths CE et al. (2016) Association of Toll-like receptor 4 (TLR4) with chronic plaque type psoriasis and psoriatic arthritis. Arch Dermatol Res 308:201-205.). TLR4 expression is increased in the epidermis of psoriatic skin, but weak in healthy controls (Shao et al., 2019). Role of TLR4 signaling is also of special importance in regulating psoriasis-like inflammation in patients with kidney failure (Ren et al., 2020Ren F, Zhang M, Zhang C and Sang H (2020) Psoriasis-like inflammation induced renal dysfunction through the TLR/NF-kappaB signal pathway. Biomed Res Int 2020: 3535264.). In mice, activation of TLR4 results in the release of pathogenic cytokines including IL-17 in the mouse model of arthritis (Chovanova et al., 2013Chovanova L, Vlcek M, Krskova K, Penesova A, Radikova Z, Rovensky J, Cholujova D, Sedlak J and Imrich R (2013) Increased production of IL-6 and IL-17 in lipopolysaccharide-stimulated peripheral mononuclears from patients with rheumatoid arthritis. Gen Physiol Biophys 32:395-404.). The constitutive IL-1β activation leads to a Th17-mediated response and a psoriatic phenotype (Shepherd et al., 2004Shepherd J, Little MC and Nicklin MJ (2004) Psoriasis-like cutaneous inflammation in mice lacking interleukin-1 receptor antagonist. J Invest Dermatol 122:665-669.).

Similar to TLR4, mutations in the caspase recruitment domain-containing protein 14 (CARD14) gene are associated with immune response in psoriatic patients via NF-κB signaling (Scudiero et al., 2011Scudiero I, Zotti T, Ferravante A, Vessichelli M, Vito P and Stilo R (2011) Alternative splicing of CARMA2/CARD14 transcripts generates protein variants with differential effect on NF-kappaB activation and endoplasmic reticulum stress-induced cell death. J Cell Physiol 226:3121-3131.) to exert the release of key psoriatic chemokines, such as CCL20 and CXCL8/IL-8 (Lowes et al., 2014Lowes MA, Suarez-Farinas M and Krueger JG (2014) Immunology of psoriasis. Annu Rev Immunol 32:227-255.). CARD14 is an intracellular scaffold protein and mainly expressed in epidermal keratinocytes. Genetic variants in the CARD14 gene have been shown to increase NF-κB activity in keratinocytes of psoriatic patients (Danis et al., 2018Danis J, Goblos A, Gal B, Sulak A, Farkas K, Torok D, Varga E, Korom I, Kemeny L, Szell M et al. (2018) Nuclear Factor kappaB activation in a type V pityriasis rubra pilaris patient harboring multiple CARD14 variants. Front Immunol9:1564.). Mouse keratinocytes lacking CARD14 produce reduced IL-17A due to the inactivation of NF-κB and mitogen-activated protein kinase (MAPK) pathways (Wang et al., 2018Wang M, Zhang S, Zheng G, Huang J, Songyang Z, Zhao X and Lin X (2018) Gain-of-Function mutation of Card14 leads to spontaneous psoriasis-like skin inflammation through enhanced keratinocyte response to IL-17A. Immunity 49:66-79.e5.).

Investigations on the effects of PSORS1C3, CARD14, and TLR4 polymorphisms are gradually increasing in the field of biomarker study in inflammatory diseases, such as psoriasis (Holm et al., 2005Holm SJ, Sanchez F, Carlen LM, Mallbris L, Stahle M and O’Brien KP (2005) HLA-Cw*0602 associates more strongly to psoriasis in the Swedish population than variants of the novel 6p21.3 gene PSORS1C3. Acta Derm Venereol 85:2-8.; Scudiero et al., 2011Scudiero I, Zotti T, Ferravante A, Vessichelli M, Vito P and Stilo R (2011) Alternative splicing of CARMA2/CARD14 transcripts generates protein variants with differential effect on NF-kappaB activation and endoplasmic reticulum stress-induced cell death. J Cell Physiol 226:3121-3131.; Smith et al., 2016Smith RL, Hebert HL, Massey J, Bowes J, Marzo-Ortega H, Ho P, McHugh NJ, Worthington J, Barton A, Griffiths CE et al. (2016) Association of Toll-like receptor 4 (TLR4) with chronic plaque type psoriasis and psoriatic arthritis. Arch Dermatol Res 308:201-205.). In this study, SNP profiling of PSORS1C3, CARD14, and TLR4 genes in 71 patients with psoriasis and 46 healthy individuals by direct DNA sequencing was investigated to determine disease-associated SNPs. Besides, inflammatory expression of psoriatic patients was also assessed by enzyme-linked immunosorbent assay (ELISA) to determine the relationship between serum level of cytokines and the presence of unusual genotypes.

Material and Methods

Patients and control subjects

A total of untreated 71 psoriatic patients and 46 healthy volunteers used as controls were recruited into the study at the Thien Phu Duong Traditional Medical Clinic, Hanoi, Vietnam. The diagnosis of psoriasis was based on the 2016 WHO criteria (World Health Organization., 2016World Health Organization (2016) Global report on psoriasis, World Health Organization (2016) Global report on psoriasis, https://apps.who.int/iris/handle/10665/204417 (accessed 28 July 2016).
https://apps.who.int/iris/handle/10665/2... ), including sharply demarcated round-oval erythematous plaques with loosely adherent silvery-white scales, especially affecting the elbows, knees, lumbosacral area, intergluteal cleft, and scalp. No individuals in the control population took any medication or suffered from any known acute or chronic disease. All patients and volunteers gave a written consent to participate in the study. Person care and experimental procedures were performed according to the Vietnamese law for the welfare of humans and were approved by the Ethical Committee of the Institute of Genome Research, Vietnam Academy of Science and Technology and all experimental protocols on human subjects were in accordance with Helsinki Declaration of 1975, as revised in 2008.

Sample size calculation and power of study

This study was designed to demonstrate 40% mean difference with 80% power and 5% significance level, a sample size of 40 in each group was calculated as described elsewhere (In et al., 2020In J, Kang H, Kim JH, Kim TK, Ahn EJ, Lee DK, Lee S and Park JH (2020) Tips for troublesome sample-size calculation. Korean J Anesthesiol 73:114-20.). To allow for study error and attrition, 71 psoriatic patients and 46 healthy individuals were included in this investigation.

DNA sequencing of PSORS1C3, CARD14 and TLR4

Genomic DNA was isolated from peripheral blood samples using a DNeasy blood and tissue kit (Qiagen). To determine polymorphisms of the PSORS1C3, CARD14 and TLR4 genes, polymerase chain reaction (PCR) and DNA sequencing (3500 Genetic Analyzers, Thermo Scientific) were performed as previously described (Trang et al., 2022Trang DT, Giang NH, Trang BK, Ngoc NT, Giang NV, Canh NX, Vuong NB and Xuan NT(2022) Prevalence of CYLD mutations in Vietnamese patients with polycythemia vera. Adv Clin Exp Med 31:369-380). The GenBank accession numbers AY484516.1, NM_001366385.1 and NM_138554.5 were used for DNA sequence analysis of PSORS1C3, CARD14 and TLR4, respectively, by using primers: PSORS1C3-F: 5’- TTTGGATGTGTCAGATTTAAGGCC-3’ and PSORS1C3-R: 5’- AATAACGAATGCAGCTGCACAT-3’; CARD14 -F: 5’- CTGCAGTGAGCAAAGCAGAC-3’ and CARD14-R: 5’- CAGGTGAGTGTGGGAATGTG-3’; and TLR4-F: 5’- TTGGTCCACAACGGTTCTCTG-3’ and TLR4-R: 5’- CTGGATGGGGTTTCCTGTCA-3’. The amplification product lengths of PSORS1C3, CARD14 and TLR4 were 665, 399 and 737bp, respectively. All obtained PCR fragments were purified with a GeneJET PCR purification kit (Thermo Scientific). The PCR products were sequenced on both strands with the same primers used for the PCR.

Cytokine quantification

Sera were isolated from the blood samples of psoriatic patients and healthy subjects and stored at -20 ˚C until used for ELISA. TNF-α, IL-6, and IL-17A concentrations were determined by using ELISA kits (Thermo Scientific) according to the manufacturer’s protocol.

Data analysis

Data related to the human PSORS1C3, CARD14 and TLR4 genes was collected from NCBI (https://www.ncbi.nlm.nih.gov/). The information for the SNP ID of these genes was retrieved from the NCBI’s SNP database (https://www.ncbi.nlm.nih.gov/snp/). Bioedit software was used for the initial analysis of the sequences.

To analyze the functional consequence of the SNPs in TLR4 gene, a PolyPhen2 program (http://genetics.bwh.harvard.edu/pph2/index.shtml) was used. The PolyPhen-2 score varies from 0.0 (tolerated) to 1.0 (deleterious), in which the SNPs were designated “probably damaging”, “potentially damaging”, “benign” or “unknown”. In addition, the possible impact of the intronic SNPs on slicing was predicted by SD-Score (Ohno et al., 2018Ohno K, Takeda JI and Masuda A (2018) Rules and tools to predict the splicing effects of exonic and intronic mutations. Wiley Interdiscip Rev RNA 9. doi: 10.1002/wrna.1451
https://doi.org/10.1002/wrna.1451... ) or MaxEntScan (Jian et al., 2014Jian X, Boerwinkle E and Liu X (2014) In silico tools for splicing defect prediction: a survey from the viewpoint of end users. Genet Med 16:497-503.) predictor programs.

Statistical analysis

The SPSS version 20 (IBM, New York, USA) was used for statistical analysis. To examine the genotype association of control and patient groups, Fisher’s exact test was used for SNPs with expected sample sizes less than 20 and Chi-squared test for those with larger expected sample sizes. The odds ratios (OR) and 95% confidence intervals (CI) were calculated by the logistic regression analysis as described elsewhere (Szumilas et al., 2010Szumilas M (2010) Explaining odds ratios. J Can Acad Child Adolesc Psychiatry 19:227-229.). The difference in cytokine levels among the SNPs, control and patient groups was tested for significance using the Mann-Whitney U test. The linkage disequilibrium (LD) analysis was calculated using the R Package LDlinkR. In all statistical analyses, the level of significance was determined at the level ofp< 0.05 and two-sided.

Results

Association between PSORS1C3, CARD14 and TLR4 gene polymorphisms and psoriasis

Firstly, sequencing of the PSORS1C3 gene identified 9 nucleotide changes including, rs887464 G>A, rs3868542 A>G, rs11507945 C>T, rs3871247 C>T, rs369029873 G>A, rs3130506 C>T, rs3871246 A>G, rs11967629 G>A and +280 G>A in the 5’ flanking region (Tables 1, 2 and Figure 1). Among the 9 SNPs found, the 4 genotypes including rs887464 AA, rs11507945 TT, rs11967629 AA and +280 GA in PSORS1C3 gene showed significantly higher frequencies in cases (25.35%, 11.27%, 11.27% and 32.39%, respectively) compared to controls (4.35%, 0%, 0% and 13.04%, respectively). The genotype distribution of the 9 SNPs, except for the SNP rs887464 was in agreement with a Hardy-Weinberg equilibrium (HWE) (p > 0.05). In addition, we noted that the minor allele frequency (MAF) of the SNPs rs11507945, rs3871247, rs3871246, rs11967629 and +280 G>A was higher, whereas the MAF of the SNPs rs369029873 and rs3130506 was lower in cases compared to controls (Table 1).

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Table 1 -
General information on SNPs and haplotypes of TLR4, CARD14 and PSORS1C3 genes in psoriatic patients and controls.

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Table 2-
Comparison of genotype frequencies of TLR4, CARD14 and PSORS1C3 variants between psoriatic patients and controls.

Figure 1-
Polymorphisms of PSORS1C3 gene in psoriatic patients and controls. Partial sequence chromatograms of PSORS1C3 gene from wildtype (1^st panels) and variant (2^nd and 3^rd panels) genotypes of the rs887464 G>A, rs3868542 A>G, rs11507945 C>T, rs3871247 C>T, rs369029873 G>A, rs3130506 C>T, rs3871246 A>G, rs11967629 G>A and +280 G>A polymorphisms are shown. Arrows indicate the location of the base changes.

Next, sequencing of CARD14 gene determined 8 nucleotide changes, including a SNP rs11653893 A>G in intron 20; 02 SNPs c.3285+54 C>G and rs376428578 C>A in intron 21; 02 non-synonymous SNPs (nsSNPs) p.T812A/S (c.3150 A>G/T) and rs11652075 C>T; and 3 synonymous SNPs rs189286068 C>T, rs61757652 C>T and rs1486223942 C>T in exon 21 (Tables 1, 2 and Figure 2). The genotype distribution of the 8 SNPs, except for the intronic SNP rs376428578 was in accordance with HWE (p > 0.05) (Table 1). The MAF for the SNP rs61757652 was slightly lower, whereas the MAF for the 2 SNPs rs1486223942 and c.3285+54 was higher in psoriatic patients than the control group. Among these 2 SNPs, the CT genotype of the snSNP rs11652075 was slightly higher in cases than controls with the carrier frequencies of 56.33% and 39.13%, respectively (Table 2). In addition, the AG genotype of the intronic SNP rs11653893 had a higher prevalence in cases, however it was not a risk factor for psoriasis as predicted by using the SD-Score or MaxEntScan predictor program.

Figure 2-
Polymorphisms of CARD14 gene in psoriatic patients and controls. Partial sequence chromatograms of CARD14 gene from wildtype (1^st panels) and variant (2^nd and 3^rd panels) genotypes of the rs11653893 A>G, p.T812A/S (c.3150 A>G/T), rs11652075 C>T, rs189286068 C>T, rs61757652 C>T, rs1486223942 C>T, c.3285+54 C>G and rs376428578 C>A polymorphisms are shown. Arrows indicate the location of the base changes.

Finally, sequencing of TLR4 gene identified 9 nucleotide changes, including 5 SNPs rs2149356 T>G, c.331-428 T>G, c.331-200 G>A, c.331-102 T>A and c.331-1 G>C in intron 3 and 4 exonic SNPs rs770576183 G>C/A, rs1018673641 A>T, p.L101L (c.371 C>T) and p.S102S (c.376 C>T) in exon 4 (Tables 1, 2 and Figure 3A). Among the 9 SNPs found in TLR4 gene, the 2 SNPs rs770576183 G>C/A and rs1018673641 A>T were nsSNPs and the 2 remaining exonic SNPs were silent. The genotype distribution of the 9 SNPs in TLR4 gene was in agreement with the HWE (p > 0.05). Importantly, we noted that the MAF of the SNPs c.331-102 T>A, rs1018673641 A>T, p.L101L and p.S102S was significantly higher in the patient group compared to control group and the difference in the MAFs for the 5 remaining SNPs between the two groups was not observed (Table 1).

Figure 3-
Polymorphisms of TLR4 gene in psoriatic patients and controls. A: Partial sequence chromatograms of TLR4 gene from wildtype (1^st panels) and variant (2^nd and 3^rd panels) genotypes of the rs2149356 T>G, c.331-428 T>G, c.331-200 G>A, c.331-102 T>A, c.331-1 G>C, rs770576183 G>C/A, rs1018673641 A>T, p.L101L (c.371 C>T) and p.S102S (c.376 C>T) polymorphisms are shown. Arrows indicate the location of the base changes. B: Functional prediction of the SNP rs1018673641 by the Polyphen-2 program.

For determination of susceptibility to psoriasis by evaluating the deleterious effect of the nsSNPs in TLR4 gene, the results indicated that among the 2 nsSNPs, only the rs1018673641 was predicted to be probably damaging by Polyphen-2 with score of 0.788 (score range: 0-1; sensitivity: 0.85; specificity: 0.93) (Figure 3B). Accordingly, the rs1018673641 might be one of the most deleterious nsSNPs in TLR4 gene. Moreover, AT genotype of the rs1018673641 showed higher frequency in cases (15.5%) compared to healthy individuals (4.35%; p = 0.008, Table 2), while the distribution of the rs770576183 genotype frequencies was similar in the two groups.

**Haplotype and linkage disequilibrium analysis of PSORS1C3, CARD14 and TLR4 variants**

Last but not least, we tested the association of statistically inferred haplotypes with the risk of psoriasis. As shown in Figure 4, the SNPs in PSORS1C3 gene formed three haplotype blocks and contributed to eighteen haplotypes in our study (Figure 4 and Table 3). Block 1 was found to include the two SNPs rs11967629 and +280 G>A; block 2 consisted of rs3130506 and rs3871246; and block 3 comprised rs3868542, rs11507945 and rs3871247. The SNPs in CARD14 gene formed haplotype block 4, which consists of rs11653893, rs11652075 and rs61757652.

Figure 4-
Linkage disequilibrium (LD) analysis of TLR4, CARD14 and PSORS1C3 genes in psoriatic patients and controls. Linkage disequilibrium analysis shows the genotyped variants in PSORS1C3, CARD14 and TLR4 genes. D’ value was shown in the LD block.

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Table 3 -
Comparison of haplotype frequencies of TLR4, CARD14 and PSORS1C3 variants between psoriatic patients and controls.

There were five haplotypes within block 1. Using the common haplotype G-G as a reference, two haplotypes (A-G and GA-GA) were associated with increased risks of psoriasis (8.45% and 29.6% for patients vs. 0% and 13.04% for controls, p=0.007 and p=0.029, respectively), whereas another haplotype (GA-G) was significantly less frequent in cases compared with controls (36.96% vs. 9.86%, p=0.002). A total of six haplotypes were inferred within block 2, in which two haplotypes (CT-AG and T-AG) were associated with decreased risks of psoriasis (19.72% and 16.9% for patients vs. 28.26% and 26.09% for controls, p=0.07 and p=0.063, respectively). Block 3 had seven haplotypes and the wild-type haplotype A-C-C was used as a reference. The haplotype frequency of G-T-T in block 3 was 11.27% in cases, while it was completely absent in controls (p=0.002). In block 4, there were nine haplotypes. Using the wild-type haplotype A-C-C as a reference, one haplotype (AG-CT-C) was significantly associated with psoriasis susceptibility (43.67% vs. 17.4%, p=0.002) (Table 3).

In addition, we also found significant differences between cases and controls for two haplotypes (A-C-T and T-T-T) of rs1018673641-c.371-c.376 in TLR4 gene. The frequency of the T-T-T haplotype was significantly elevated (14.08% vs. 2.18%, p=0.047), whereas the A-C-T haplotype was significantly less frequent in cases compared with controls (19.56% vs. 2.82%, p<0.001) (Table 3).

Moreover, the linkage disequilibrium (LD) analysis showed a tight linkage between almost all the SNPs detected in PSORS1C3 gene (except for the rs369029873 and rs887464 variants). Of the 8 variants in the CARD14 gene, the three SNPs rs11653893, rs11652075 and rs61757652 were tightly linked. However, no haplotype block was found in the TLR4 gene (Figure 4), probably because of the small sample size.

Association between inflammatory cytokines and genotypes in psoriatic patients

TLR4 and CARD14 are known as inducers of inflammatory reaction (Scudiero et al., 2011Scudiero I, Zotti T, Ferravante A, Vessichelli M, Vito P and Stilo R (2011) Alternative splicing of CARMA2/CARD14 transcripts generates protein variants with differential effect on NF-kappaB activation and endoplasmic reticulum stress-induced cell death. J Cell Physiol 226:3121-3131.; Takeshita et al., 2017Takeshita J, Grewal S, Langan SM, Mehta NN, Ogdie A, Van Voorhees AS and Gelfand JM (2017) Psoriasis and comorbid diseases: Implications for management. J Am Acad Dermatol 76:393-403.; Tang et al., 2021Tang H, Guo Z, Tang X, Gao J, Wang W, Huang H, Zheng X, Cheng H, Sheng Y and Sun L (2021) MST1 modulates Th17 activation in psoriasis via regulating TLR4-NF-kappaB pathway. Hum Cell 34:28-36.), thus unusual genotypes in these genes may be related to the release of cytokine production in psoriatic patients. Similar to a recent study (Christophers et al., 2019Christophers E and van de Kerkhof PCM (2019) Severity, heterogeneity and systemic inflammation in psoriasis. J Eur Acad Dermatol Venereol 33:643-647.), we observed that levels of IL-6, IL-17A and TNF-α in psoriatic patients were found higher than control individuals (Figure 5A). Furthermore, the increased level of these cytokines was seen in severe psoriasis (Christophers et al., 2019Christophers E and van de Kerkhof PCM (2019) Severity, heterogeneity and systemic inflammation in psoriasis. J Eur Acad Dermatol Venereol 33:643-647.). As expected, level of IL-6 was significantly higher in patients carrying the AT genotype as compared with carriers of the AA genotype of SNP rs1018673641 in TLR4 gene (Figure 5B). However, no significant difference between levels of IL17A and TNF-α and the SNPs in PSORS1C3, CARD14 and TLR4 genes was observed (data now shown). The evidence for the association pointed out that psoriatic patients carrying the rs1018673641 AT genotype in TLR4 gene was sensitive to IL6-induced inflammatory response.

Figure 5-
Expression of inflammatory cytokines in psoriatic patients. A: Arithmetic means ± SEM (n = 46-71) of IL-6, IL-17A and TNF-α concentrations are attained from sera of healthy donors and psoriatic patients. ** (p<0.01) and *** (p<0.001) indicate significant differences from healthy donors (Mann-Whitney U test). The box plots denote the median, IQR and minimum and maximum values. B: Arithmetic means ± SEM (n = 11-60) of IL-6 concentration is attained from sera of psoriatic patients carrying the AA or AT genotype of SNP rs1018673641 in TLR4 gene. *** (p<0.001) indicates significant difference from the AA genotype (Mann-Whitney U test). The box plots denote the median, IQR and minimum and maximum values.

Discussion

This study showed the increased risk of developing psoriasis in patients carrying SNPs in PSORS1C3, CARD14 and TLR4 genes (Holm et al., 2005Holm SJ, Sanchez F, Carlen LM, Mallbris L, Stahle M and O’Brien KP (2005) HLA-Cw*0602 associates more strongly to psoriasis in the Swedish population than variants of the novel 6p21.3 gene PSORS1C3. Acta Derm Venereol 85:2-8.; Smith et al., 2016Smith RL, Hebert HL, Massey J, Bowes J, Marzo-Ortega H, Ho P, McHugh NJ, Worthington J, Barton A, Griffiths CE et al. (2016) Association of Toll-like receptor 4 (TLR4) with chronic plaque type psoriasis and psoriatic arthritis. Arch Dermatol Res 308:201-205.; Danis et al., 2018Danis J, Goblos A, Gal B, Sulak A, Farkas K, Torok D, Varga E, Korom I, Kemeny L, Szell M et al. (2018) Nuclear Factor kappaB activation in a type V pityriasis rubra pilaris patient harboring multiple CARD14 variants. Front Immunol9:1564.). Unlike PSORS1C3 gene, the functional study of TLR4 and CARD14 genes demonstrates that they play important roles in regulating pro-inflammatory gene expression through activation of intracellular signaling such as NF-κB or MAPK (Wang et al., 2018Wang M, Zhang S, Zheng G, Huang J, Songyang Z, Zhao X and Lin X (2018) Gain-of-Function mutation of Card14 leads to spontaneous psoriasis-like skin inflammation through enhanced keratinocyte response to IL-17A. Immunity 49:66-79.e5.; Tang et al., 2021Tang H, Guo Z, Tang X, Gao J, Wang W, Huang H, Zheng X, Cheng H, Sheng Y and Sun L (2021) MST1 modulates Th17 activation in psoriasis via regulating TLR4-NF-kappaB pathway. Hum Cell 34:28-36.). Therefore, genetic variation of TLR4 and CARD14 genes might be the contributing risk factors for psoriasis by modulating the cellular physiological processes.

Little is known about the functional role of PSORS1C3 gene in modulating inflammatory response, the association of PSORS1C3 polymorphisms with psoriasis in various population has been well documented (Holm et al., 2005Holm SJ, Sanchez F, Carlen LM, Mallbris L, Stahle M and O’Brien KP (2005) HLA-Cw*0602 associates more strongly to psoriasis in the Swedish population than variants of the novel 6p21.3 gene PSORS1C3. Acta Derm Venereol 85:2-8.; Chang et al., 2006Chang YT, Chou CT, Shiao YM, Lin MW, Yu CW, Chen CC, Huang CH, Lee DD, Liu HN, Wang WJ et al. (2006) Psoriasis vulgaris in Chinese individuals is associated with PSORS1C3 and CDSN genes. Br J Dermatol 155:663-669.). Similar to the Chinese population (Chang et al., 2006Chang YT, Chou CT, Shiao YM, Lin MW, Yu CW, Chen CC, Huang CH, Lee DD, Liu HN, Wang WJ et al. (2006) Psoriasis vulgaris in Chinese individuals is associated with PSORS1C3 and CDSN genes. Br J Dermatol 155:663-669.), we observed that frequencies of the 2 SNPs -26 C>T (rs3871247) and +246 A>G (rs3871246) in the PSORS1C3 gene were comparable in the two groups, whereas they are previously reported to be susceptibility SNPs for psoriasis in Swedish population (Holm et al., 2005Holm SJ, Sanchez F, Carlen LM, Mallbris L, Stahle M and O’Brien KP (2005) HLA-Cw*0602 associates more strongly to psoriasis in the Swedish population than variants of the novel 6p21.3 gene PSORS1C3. Acta Derm Venereol 85:2-8.). In addition, similar to a recent study by Holm et al. (2005Holm SJ, Sanchez F, Carlen LM, Mallbris L, Stahle M and O’Brien KP (2005) HLA-Cw*0602 associates more strongly to psoriasis in the Swedish population than variants of the novel 6p21.3 gene PSORS1C3. Acta Derm Venereol 85:2-8.), the presence of the SNP rs3868542 in PSORS1C3 gene was unaffected patients with psoriasis. Moreover, the present study demonstrated for the first time that, of the 4 remaining genotyped SNPs in the 5’ flanking region, all the rs887464 AA, rs11507945 TT, rs11967629 AA and +280 GA genotypes were prominently associated with psoriasis. The evidences noted that disease susceptibility SNPs in the PSORS1C3 gene were different from one population to another.

The regulatory role of inflammatory skin disorders is reported mediated through CARD14 signaling. Recently, the SNP rs11653893 in the CARD14 is detected in patients with pityriasis rubra pilaris (Gal et al., 2019Gal B, Goblos A, Danis J, Farkas K, Sulak A, Varga E, Nagy N, Szell M, Kemeny L and Bata-Csorgo Z (2019) The management and genetic background of pityriasis rubra pilaris: a single-centre experience. J Eur Acad Dermatol Venereol 33:944-949.), a rare form of psoriatic skin disease. Similarly, we observed that carriers of the AG genotype were detected at a higher frequency compared to patients carrying the AA or GG genotype in SNP rs11653893. A recent report by Tsoi et al. (2012Tsoi LC, Spain SL, Knight J, Ellinghaus E, Stuart PE, Capon F, Ding J, Li Y, Tejasvi T, Gudjonsson JE et al. (2012) Identification of 15 new psoriasis susceptibility loci highlights the role of innate immunity. Nat Genet 44:1341-1348.) reveals that the SNP rs11652075 in CARD14 gene is sensitive with psoriasis in Caucasian population, while we observed an increased frequency of the rs11652075 CT genotype in patient group, but not reaching to statistical significance (p=0.124).

Similar to CARD14 gene, the role of TLR4 gene is related to the development of a number of inflammatory diseases, such as psoriasis (Smith et al., 2016Smith RL, Hebert HL, Massey J, Bowes J, Marzo-Ortega H, Ho P, McHugh NJ, Worthington J, Barton A, Griffiths CE et al. (2016) Association of Toll-like receptor 4 (TLR4) with chronic plaque type psoriasis and psoriatic arthritis. Arch Dermatol Res 308:201-205.). Among the 9 SNPs in TLR4 gene observed, the rs1018673641 was found to be most likely to exert deleterious effect. Role of TLR4 is especially important in mediating chronic inflammatory condition (Takeshita et al., 2017Takeshita J, Grewal S, Langan SM, Mehta NN, Ogdie A, Van Voorhees AS and Gelfand JM (2017) Psoriasis and comorbid diseases: Implications for management. J Am Acad Dermatol 76:393-403.). Expression of TLR4 is enhanced in the epidermis of psoriatic skin (Shao et al., 2019Shao S, Fang H, Dang E, Xue K, Zhang J, Li B, Qiao H, Cao T, Zhuang Y, Shen S et al. (2019) Neutrophil extracellular traps promote inflammatory responses in psoriasis via activating epidermal TLR4/IL-36R crosstalk. Front Immunol 10:746.), leading to infiltration of Th17 cells and their activation (Tang et al., 2021Tang H, Guo Z, Tang X, Gao J, Wang W, Huang H, Zheng X, Cheng H, Sheng Y and Sun L (2021) MST1 modulates Th17 activation in psoriasis via regulating TLR4-NF-kappaB pathway. Hum Cell 34:28-36.). The release of cytokines, such as IL-1β (Shepherd et al., 2004Shepherd J, Little MC and Nicklin MJ (2004) Psoriasis-like cutaneous inflammation in mice lacking interleukin-1 receptor antagonist. J Invest Dermatol 122:665-669.) and TNF-α/IL-23/IL-17 (Cai et al., 2019Cai Y, Xue F, Quan C, Qu M, Liu N, Zhang Y, Fleming C, Hu X, Zhang HG, Weichselbaum R et al. (2019) A critical role of the IL-1beta-IL-1R signaling pathway in skin inflammation and psoriasis pathogenesis. J Invest Dermatol 139:146-156.) by TLR4-mediated inflammatory immune cells is related to the severity of psoriasis (Ren et al., 2020Ren F, Zhang M, Zhang C and Sang H (2020) Psoriasis-like inflammation induced renal dysfunction through the TLR/NF-kappaB signal pathway. Biomed Res Int 2020: 3535264.). Besides, several SNPs in TLR4 gene have been reported associated with psoriasis susceptibility (Smith et al., 2016Smith RL, Hebert HL, Massey J, Bowes J, Marzo-Ortega H, Ho P, McHugh NJ, Worthington J, Barton A, Griffiths CE et al. (2016) Association of Toll-like receptor 4 (TLR4) with chronic plaque type psoriasis and psoriatic arthritis. Arch Dermatol Res 308:201-205.), we additionally indicated that the AT genotype of the SNP rs1018673641 in TLR4 gene could be the high-risk genotype for psoriasis.

Interestingly, we demonstrated that all the three haplotypes (A-G, GA-GA and G-T-T) in PSORS1C3 gene, the AG-CT-C haplotype in CARD14 gene and the T-T-T haplotype in TLR4 gene were detected at higher frequencies in patients with psoriasis compared to controls (Table 3). Unlike PSORS1C3 gene, reports on the effects of CARD14 and TLR4 haplotypes in psoriasis susceptibility are limited (Sugiura et al., 2014Sugiura K, Muto M and Akiyama M (2014) CARD14 c.526G>C (p.Asp176His) is a significant risk factor for generalized pustular psoriasis with psoriasis vulgaris in the Japanese cohort. J Invest Dermatol 134:1755-1757.; Traks et al., 2015Traks T, Keermann M, Karelson M, Ratsep R, Reimann E, Silm H, Vasar E, Koks S and Kingo K (2015) Polymorphisms in Toll-like receptor genes are associated with vitiligo. Front Genet6:278.). The haplotypes found in PSORS1C3, CARD14 and TLR4 genes were reported for the first time in this finding.

Finally, we observed enhanced expression of inflammatory cytokines IL-6, IL-17A and TNF-α in sera of psoriatic patients. Similarly, the increased level of these cytokines is seen in severe psoriasis (Christophers et al., 2019Christophers E and van de Kerkhof PCM (2019) Severity, heterogeneity and systemic inflammation in psoriasis. J Eur Acad Dermatol Venereol 33:643-647.). More importantly, level of IL-6 was found higher in carriers of the AT genotype as compared to patients carrying the AA genotype of SNP rs1018673641 in TLR4 gene. As TLR4 is known to play a crucial role in the regulation of immune response, an investigation in a mouse model showed that serum cytokine productions secreted from immune cells are defected in TLR4-deficient mice (Hollingsworth et al., 2006Hollingsworth JW, Whitehead GS, Lin KL, Nakano H, Gunn MD, Schwartz DA and Cook DN (2006) TLR4 signaling attenuates ongoing allergic inflammation. J Immunol 176:5856-5862.). A recent study indicates that psoriasis-like inflammation damages the renal function via the TLR4-mediated IL-6 production in mice (Ren et al., 2020Ren F, Zhang M, Zhang C and Sang H (2020) Psoriasis-like inflammation induced renal dysfunction through the TLR/NF-kappaB signal pathway. Biomed Res Int 2020: 3535264.). In this work, we predict that IL-6-mediated inflammation in psoriasis could be involved in variant TLR4 genotypes.

There are several potential limitations in the current study. The sample size was not sufficient for statistical measurements to verify significant relationship between the SNPs in PSORS1C3, CARD14 and TLR4 genes and psoriasis susceptibility in the Vietnamese population. Besides, further functional research is necessary for investigating the regulatory effects of the SNP rs1018673641 in TLR4 gene on inflammatory response in psoriasis.

In conclusion, the deleterious effect of the SNP rs1018673641 in TLR4 gene could partially contribute to chronic inflammation in psoriasis and be a good candidate for further study on its role in regulating functional activation of immune cells in psoriatic patients.

Acknowledgements

This research is funded by Graduate University of Science and Technology, Vietnam Academy of Science and Technology under grant number GUST.STS.ĐT2019-SH02.

References

Afonina IS, Van Nuffel E and Beyaert R (2021) Immune responses and therapeutic options in psoriasis. Cell Mol Life Sci 78: 2709-2727.
Cai Y, Xue F, Quan C, Qu M, Liu N, Zhang Y, Fleming C, Hu X, Zhang HG, Weichselbaum R et al (2019) A critical role of the IL-1beta-IL-1R signaling pathway in skin inflammation and psoriasis pathogenesis. J Invest Dermatol 139:146-156.
Chang YT, Chou CT, Shiao YM, Lin MW, Yu CW, Chen CC, Huang CH, Lee DD, Liu HN, Wang WJ et al (2006) Psoriasis vulgaris in Chinese individuals is associated with PSORS1C3 and CDSN genes. Br J Dermatol 155:663-669.
Chovanova L, Vlcek M, Krskova K, Penesova A, Radikova Z, Rovensky J, Cholujova D, Sedlak J and Imrich R (2013) Increased production of IL-6 and IL-17 in lipopolysaccharide-stimulated peripheral mononuclears from patients with rheumatoid arthritis. Gen Physiol Biophys 32:395-404.
Christophers E and van de Kerkhof PCM (2019) Severity, heterogeneity and systemic inflammation in psoriasis. J Eur Acad Dermatol Venereol 33:643-647.
Danis J, Goblos A, Gal B, Sulak A, Farkas K, Torok D, Varga E, Korom I, Kemeny L, Szell M et al (2018) Nuclear Factor kappaB activation in a type V pityriasis rubra pilaris patient harboring multiple CARD14 variants. Front Immunol9:1564.
Gal B, Goblos A, Danis J, Farkas K, Sulak A, Varga E, Nagy N, Szell M, Kemeny L and Bata-Csorgo Z (2019) The management and genetic background of pityriasis rubra pilaris: a single-centre experience. J Eur Acad Dermatol Venereol 33:944-949.
Griffiths CE and Barker JN (2007) Pathogenesis and clinical features of psoriasis. Lancet 370:263-271.
Hollingsworth JW, Whitehead GS, Lin KL, Nakano H, Gunn MD, Schwartz DA and Cook DN (2006) TLR4 signaling attenuates ongoing allergic inflammation. J Immunol 176:5856-5862.
Holm SJ, Sanchez F, Carlen LM, Mallbris L, Stahle M and O’Brien KP (2005) HLA-Cw*0602 associates more strongly to psoriasis in the Swedish population than variants of the novel 6p21.3 gene PSORS1C3. Acta Derm Venereol 85:2-8.
In J, Kang H, Kim JH, Kim TK, Ahn EJ, Lee DK, Lee S and Park JH (2020) Tips for troublesome sample-size calculation. Korean J Anesthesiol 73:114-20.
Jian X, Boerwinkle E and Liu X (2014) In silico tools for splicing defect prediction: a survey from the viewpoint of end users. Genet Med 16:497-503.
Lowes MA, Suarez-Farinas M and Krueger JG (2014) Immunology of psoriasis. Annu Rev Immunol 32:227-255.
Mease PJ (2015) Inhibition of interleukin-17, interleukin-23 and the TH17 cell pathway in the treatment of psoriatic arthritis and psoriasis. Curr Opin Rheumatol 27:127-133.
Mohd Affandi A, Khan I and Ngah Saaya N (2018) Epidemiology and clinical features of adult patients with psoriasis in Malaysia: 10-year review from the Malaysian Psoriasis Registry (2007-2016). Dermatol Res Pract 2018:4371471.
Ohno K, Takeda JI and Masuda A (2018) Rules and tools to predict the splicing effects of exonic and intronic mutations. Wiley Interdiscip Rev RNA 9. doi: 10.1002/wrna.1451
» https://doi.org/10.1002/wrna.1451
Parisi R, Symmons DP, Griffiths CE, Ashcroft DM; Identification and Management of Psoriasis and Associated ComorbidiTy (IMPACT) project team (2013) Global epidemiology of psoriasis: A systematic review of incidence and prevalence. J Invest Dermatol 133:377-385.
Ren F, Zhang M, Zhang C and Sang H (2020) Psoriasis-like inflammation induced renal dysfunction through the TLR/NF-kappaB signal pathway. Biomed Res Int 2020: 3535264.
Scudiero I, Zotti T, Ferravante A, Vessichelli M, Vito P and Stilo R (2011) Alternative splicing of CARMA2/CARD14 transcripts generates protein variants with differential effect on NF-kappaB activation and endoplasmic reticulum stress-induced cell death. J Cell Physiol 226:3121-3131.
Shao S, Fang H, Dang E, Xue K, Zhang J, Li B, Qiao H, Cao T, Zhuang Y, Shen S et al (2019) Neutrophil extracellular traps promote inflammatory responses in psoriasis via activating epidermal TLR4/IL-36R crosstalk. Front Immunol 10:746.
Shepherd J, Little MC and Nicklin MJ (2004) Psoriasis-like cutaneous inflammation in mice lacking interleukin-1 receptor antagonist. J Invest Dermatol 122:665-669.
Smith RL, Hebert HL, Massey J, Bowes J, Marzo-Ortega H, Ho P, McHugh NJ, Worthington J, Barton A, Griffiths CE et al (2016) Association of Toll-like receptor 4 (TLR4) with chronic plaque type psoriasis and psoriatic arthritis. Arch Dermatol Res 308:201-205.
Sugiura K, Muto M and Akiyama M (2014) CARD14 c.526G>C (p.Asp176His) is a significant risk factor for generalized pustular psoriasis with psoriasis vulgaris in the Japanese cohort. J Invest Dermatol 134:1755-1757.
Szumilas M (2010) Explaining odds ratios. J Can Acad Child Adolesc Psychiatry 19:227-229.
Takeshita J, Grewal S, Langan SM, Mehta NN, Ogdie A, Van Voorhees AS and Gelfand JM (2017) Psoriasis and comorbid diseases: Implications for management. J Am Acad Dermatol 76:393-403.
Tang H, Guo Z, Tang X, Gao J, Wang W, Huang H, Zheng X, Cheng H, Sheng Y and Sun L (2021) MST1 modulates Th17 activation in psoriasis via regulating TLR4-NF-kappaB pathway. Hum Cell 34:28-36.
Traks T, Keermann M, Karelson M, Ratsep R, Reimann E, Silm H, Vasar E, Koks S and Kingo K (2015) Polymorphisms in Toll-like receptor genes are associated with vitiligo. Front Genet6:278.
Trang DT, Giang NH, Trang BK, Ngoc NT, Giang NV, Canh NX, Vuong NB and Xuan NT(2022) Prevalence of CYLD mutations in Vietnamese patients with polycythemia vera. Adv Clin Exp Med 31:369-380
Tsoi LC, Spain SL, Knight J, Ellinghaus E, Stuart PE, Capon F, Ding J, Li Y, Tejasvi T, Gudjonsson JE et al (2012) Identification of 15 new psoriasis susceptibility loci highlights the role of innate immunity. Nat Genet 44:1341-1348.
van den Bogaard EH, Tjabringa GS, Joosten I, Vonk-Bergers M, van Rijssen E, Tijssen HJ, Erkens M, Schalkwijk J and Koenen H (2014) Crosstalk between keratinocytes and T cells in a 3D microenvironment: a model to study inflammatory skin diseases. J Invest Dermatol 134:719-727.
Wagner EF, Schonthaler HB, Guinea-Viniegra J and Tschachler E (2010) Psoriasis: what we have learned from mouse models. Nat Rev Rheumatol 6:704-714.
Wang M, Zhang S, Zheng G, Huang J, Songyang Z, Zhao X and Lin X (2018) Gain-of-Function mutation of Card14 leads to spontaneous psoriasis-like skin inflammation through enhanced keratinocyte response to IL-17A. Immunity 49:66-79.e5.

Internet Resources

World Health Organization (2016) Global report on psoriasis, World Health Organization (2016) Global report on psoriasis, https://apps.who.int/iris/handle/10665/204417 (accessed 28 July 2016).
» https://apps.who.int/iris/handle/10665/204417

#
These authors contributed equally to this work.

Associate Editor:

Jorge Lopez-Camelo

Publication Dates

Publication in this collection
07 Nov 2022
Date of issue
2022

History

Received
10 Mar 2022
Accepted
03 Oct 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Afonina IS, Van Nuffel E and Beyaert R (2021) Immune responses and therapeutic options in psoriasis. Cell Mol Life Sci 78: 2709-2727.

[2] Cai Y, Xue F, Quan C, Qu M, Liu N, Zhang Y, Fleming C, Hu X, Zhang HG, Weichselbaum R et al (2019) A critical role of the IL-1beta-IL-1R signaling pathway in skin inflammation and psoriasis pathogenesis. J Invest Dermatol 139:146-156.

[3] Chang YT, Chou CT, Shiao YM, Lin MW, Yu CW, Chen CC, Huang CH, Lee DD, Liu HN, Wang WJ et al (2006) Psoriasis vulgaris in Chinese individuals is associated with PSORS1C3 and CDSN genes. Br J Dermatol 155:663-669.

[4] Chovanova L, Vlcek M, Krskova K, Penesova A, Radikova Z, Rovensky J, Cholujova D, Sedlak J and Imrich R (2013) Increased production of IL-6 and IL-17 in lipopolysaccharide-stimulated peripheral mononuclears from patients with rheumatoid arthritis. Gen Physiol Biophys 32:395-404.

[5] Christophers E and van de Kerkhof PCM (2019) Severity, heterogeneity and systemic inflammation in psoriasis. J Eur Acad Dermatol Venereol 33:643-647.

[6] Danis J, Goblos A, Gal B, Sulak A, Farkas K, Torok D, Varga E, Korom I, Kemeny L, Szell M et al (2018) Nuclear Factor kappaB activation in a type V pityriasis rubra pilaris patient harboring multiple CARD14 variants. Front Immunol9:1564.

[7] Gal B, Goblos A, Danis J, Farkas K, Sulak A, Varga E, Nagy N, Szell M, Kemeny L and Bata-Csorgo Z (2019) The management and genetic background of pityriasis rubra pilaris: a single-centre experience. J Eur Acad Dermatol Venereol 33:944-949.

[8] Griffiths CE and Barker JN (2007) Pathogenesis and clinical features of psoriasis. Lancet 370:263-271.

[9] Hollingsworth JW, Whitehead GS, Lin KL, Nakano H, Gunn MD, Schwartz DA and Cook DN (2006) TLR4 signaling attenuates ongoing allergic inflammation. J Immunol 176:5856-5862.

[10] Holm SJ, Sanchez F, Carlen LM, Mallbris L, Stahle M and O’Brien KP (2005) HLA-Cw*0602 associates more strongly to psoriasis in the Swedish population than variants of the novel 6p21.3 gene PSORS1C3. Acta Derm Venereol 85:2-8.

[11] In J, Kang H, Kim JH, Kim TK, Ahn EJ, Lee DK, Lee S and Park JH (2020) Tips for troublesome sample-size calculation. Korean J Anesthesiol 73:114-20.

[12] Jian X, Boerwinkle E and Liu X (2014) In silico tools for splicing defect prediction: a survey from the viewpoint of end users. Genet Med 16:497-503.

[13] Lowes MA, Suarez-Farinas M and Krueger JG (2014) Immunology of psoriasis. Annu Rev Immunol 32:227-255.

[14] Mease PJ (2015) Inhibition of interleukin-17, interleukin-23 and the TH17 cell pathway in the treatment of psoriatic arthritis and psoriasis. Curr Opin Rheumatol 27:127-133.

[15] Mohd Affandi A, Khan I and Ngah Saaya N (2018) Epidemiology and clinical features of adult patients with psoriasis in Malaysia: 10-year review from the Malaysian Psoriasis Registry (2007-2016). Dermatol Res Pract 2018:4371471.

[16] Ohno K, Takeda JI and Masuda A (2018) Rules and tools to predict the splicing effects of exonic and intronic mutations. Wiley Interdiscip Rev RNA 9. doi: 10.1002/wrna.1451
» https://doi.org/10.1002/wrna.1451

[17] Parisi R, Symmons DP, Griffiths CE, Ashcroft DM; Identification and Management of Psoriasis and Associated ComorbidiTy (IMPACT) project team (2013) Global epidemiology of psoriasis: A systematic review of incidence and prevalence. J Invest Dermatol 133:377-385.

[18] Ren F, Zhang M, Zhang C and Sang H (2020) Psoriasis-like inflammation induced renal dysfunction through the TLR/NF-kappaB signal pathway. Biomed Res Int 2020: 3535264.

[19] Scudiero I, Zotti T, Ferravante A, Vessichelli M, Vito P and Stilo R (2011) Alternative splicing of CARMA2/CARD14 transcripts generates protein variants with differential effect on NF-kappaB activation and endoplasmic reticulum stress-induced cell death. J Cell Physiol 226:3121-3131.

[20] Shao S, Fang H, Dang E, Xue K, Zhang J, Li B, Qiao H, Cao T, Zhuang Y, Shen S et al (2019) Neutrophil extracellular traps promote inflammatory responses in psoriasis via activating epidermal TLR4/IL-36R crosstalk. Front Immunol 10:746.

[21] Shepherd J, Little MC and Nicklin MJ (2004) Psoriasis-like cutaneous inflammation in mice lacking interleukin-1 receptor antagonist. J Invest Dermatol 122:665-669.

[22] Smith RL, Hebert HL, Massey J, Bowes J, Marzo-Ortega H, Ho P, McHugh NJ, Worthington J, Barton A, Griffiths CE et al (2016) Association of Toll-like receptor 4 (TLR4) with chronic plaque type psoriasis and psoriatic arthritis. Arch Dermatol Res 308:201-205.

[23] Sugiura K, Muto M and Akiyama M (2014) CARD14 c.526G>C (p.Asp176His) is a significant risk factor for generalized pustular psoriasis with psoriasis vulgaris in the Japanese cohort. J Invest Dermatol 134:1755-1757.

[24] Szumilas M (2010) Explaining odds ratios. J Can Acad Child Adolesc Psychiatry 19:227-229.

[25] Takeshita J, Grewal S, Langan SM, Mehta NN, Ogdie A, Van Voorhees AS and Gelfand JM (2017) Psoriasis and comorbid diseases: Implications for management. J Am Acad Dermatol 76:393-403.

[26] Tang H, Guo Z, Tang X, Gao J, Wang W, Huang H, Zheng X, Cheng H, Sheng Y and Sun L (2021) MST1 modulates Th17 activation in psoriasis via regulating TLR4-NF-kappaB pathway. Hum Cell 34:28-36.

[27] Traks T, Keermann M, Karelson M, Ratsep R, Reimann E, Silm H, Vasar E, Koks S and Kingo K (2015) Polymorphisms in Toll-like receptor genes are associated with vitiligo. Front Genet6:278.

[28] Trang DT, Giang NH, Trang BK, Ngoc NT, Giang NV, Canh NX, Vuong NB and Xuan NT(2022) Prevalence of CYLD mutations in Vietnamese patients with polycythemia vera. Adv Clin Exp Med 31:369-380

[29] Tsoi LC, Spain SL, Knight J, Ellinghaus E, Stuart PE, Capon F, Ding J, Li Y, Tejasvi T, Gudjonsson JE et al (2012) Identification of 15 new psoriasis susceptibility loci highlights the role of innate immunity. Nat Genet 44:1341-1348.

[30] van den Bogaard EH, Tjabringa GS, Joosten I, Vonk-Bergers M, van Rijssen E, Tijssen HJ, Erkens M, Schalkwijk J and Koenen H (2014) Crosstalk between keratinocytes and T cells in a 3D microenvironment: a model to study inflammatory skin diseases. J Invest Dermatol 134:719-727.

[31] Wagner EF, Schonthaler HB, Guinea-Viniegra J and Tschachler E (2010) Psoriasis: what we have learned from mouse models. Nat Rev Rheumatol 6:704-714.

[32] Wang M, Zhang S, Zheng G, Huang J, Songyang Z, Zhao X and Lin X (2018) Gain-of-Function mutation of Card14 leads to spontaneous psoriasis-like skin inflammation through enhanced keratinocyte response to IL-17A. Immunity 49:66-79.e5.

SNP/Gene	Position	Type of Variant	Allele	MAF in psoriasis group	MAF in control group	1000G MAF	HWE in Psoriasis Group (p)	HWE in Control Group (p)	HWE in all Population (p)
PSORS1C3/rs887464	6:31178143	5′ Flanking	G>A	0.4014	0.3043	0.3722	0.0053	0.2895	0.1897
PSORS1C3/rs3868542	6:31178062	5′ Flanking	A>G	0.3803	0.3696	0.41154	0.3880	0.9841	0.6268
PSORS1C3/rs11507945	6:31177978	5′ Flanking	C>T	0.3239	0.2500	0.21705	0.9567	0.0777	0.6270
PSORS1C3/rs3871247	6:31177925	5′ Flanking	C>T	0.3873	0.3370	0.41154	0.5017	0.3410	0.9970
PSORS1C3/rs369029873	6:31177834	5′ Flanking, exon 1	G>A	0.1690	0.2065	0.00002	0.2303	0.2105	0.0516
PSORS1C3/rs3130506	6:31177674	5′ Flanking, exon 1	C>T	0.6761	0.7065	0.31310	0.9706	0.3779	0.5895
PSORS1C3/rs3871246	6:31177654	5′ Flanking, exon 1	A>G	0.3592	0.3370	0.41034	0.3418	0.3410	0.9675
PSORS1C3/rs11967629	6:31177636	Splice region variant	G>A	0.3099	0.2500	0.21685	0.8061	0.0777	0.7716
PSORS1C3/+280	6:31177647	Intron	G>A	0.1620	0.0652		0.2655	0.8941	0.3101
CARD14/rs11653893	17:80205031	Intron	A>G	0.5000	0.5000	0.35863	0.2051	0.3372	0.8987
CARD14/rs189286068	17:80205039	Synonymous	C>T	0.0282	0.0326	0.00279	0.9706	0.9742	0.9459
CARD14/c.3150 p.T812A/S	17:80205070	Missense	A>G/T	0.0211	0.0213		0.9927	0.9972	0.9892
CARD14/rs11652075	17:80205094	Missense	C>T	0.5845	0.5000	0.35304	0.5550	0.3372	0.5725
CARD14/rs61757652	17:80205117	Synonymous	C>T	0.1197	0.1739	0.10004	1.3132	0.3608	0.2066
CARD14/rs1486223942	17:80205169	synonymous	C>T	0.0141	0.0000	0.00001	0.9928	N/A	0.9957
CARD14/c.3285+54	17:80205259	Intron	C>G	0.0211	0.0000		0.9836	N/A	0.9902
CARD14/rs376428578	17:80205308	Intron	C>A	0.1901	0.3696	0.00006	0.1299	0.0004	0.0007
TLR4/rs2149356	9:117711921	Intron	T>G	0.7210	0.6850	0.47883	0,9928	0,5624	0.6785
TLR4/c.331-428	9:117711961	Intron	T>G	0.1360	0.1520		0.4219	0.4767	0.2029
TLR4/c.331-200	9:117712189	Intron	G>A	0.0143	0.0109		0.9927	0.9972	0.9901
TLR4/c.331-102	9:117712277	Intron	T>A	0.0357	0.0109		0.9531	0.9972	0.9599
TLR4/c.331-1	9:117712388	Intron	G>C	0.0143	0.0109		0.9927	0.9972	0.9901
TLR4/rs770576183	9:117712401	Missense	G>C	0.0210	0.0000	0.00001	0.0000	N/A	0.0000
TLR4/rs1018673641	9:117712426	Missense	A>T	0.0790	0.0330		0.7753	0.9742	0.7873
TLR4/c.371 p.L101 L	9:117712429	Synonymous	C>T	0.1571	0.0978		0,07831	0,2105	0,01651
TLR4/c.376 p.S102S	9:117712434	Synonymous	C>T	0.1214	0.0217		0.5124	0.9887	0.6333

SNP	Gene	Test model	Controls (n=46)	Patients (n=71)	OR	95% CI	p-Value
rs887464	PSORS1C3	GG	20 (43.48%)	32 (45.07%)
		GA	24 (52.17%)	21 (29.58%)	0.5469	0.2434 - 1.2286	0.065⁽²⁾
		AA	2 (4.35%)	18 (25.35%)	5.625	1.1772 - 26.8779	0.001⁽¹⁾
rs3868542	PSORS1C3	AA	18 (39.13%)	30 (42.25%)
		AG	22 (47.83%)	28 (39.44%)	0.7636	0.3403 - 1.7136	0.44⁽²⁾
		GG	6 (13.04%)	13 (18.31%)	1.3	0.4199 - 4.0250	0.673⁽¹⁾
rs11507945	PSORS1C3	CC	23 (50%)	33 (46.48%)
		CT	23 (50%)	30 (42.25%)	0.9091	0.4249 - 1.9451	0.772⁽²⁾
		TT	0 (0%)	8 (11.27%)	11.9254	0.6558 - 216.8568	0.001⁽¹⁾
rs3871247	PSORS1C3	CC	18 (39.13%)	29 (40.85%)
		CT	25 (54.35 %)	29 (40.85%)	0.72	0.3251 - 1.5944	0.292⁽²⁾
		TT	3 (6.52%)	13 (18.3%)	2.6897	0.6724 - 10.7591	0.673⁽¹⁾
rs369029873	PSORS1C3	GG	27 (58.7%)	47 (66.2%)
rs369029873	PSORS1C3	GA	19 (41.3%)	24 (33.8%)	0.7256	0.3374 - 1.5605	0.381⁽²⁾
rs3130506	PSORS1C3	CC	2 (4.35%)	7 (9.86%)
		CT	23 (50%)	32 (45.07%)	0.3975	0.0756 - 2.0913	0.151⁽²⁾
		TT	21 (45.65%)	32 (45.07%)	0.4354	0.0824 - 2.3015	0.157⁽²⁾
rs3871246	PSORS1C3	AA	18 (39.13%)	32 (45.07%)
		AG	25 (54.35%)	27 (38.03%)	0.6075	0.2748 - 1.3431	0.131⁽²⁾
		GG	3 (6.52%)	12 (16.9%)	2.25	0.5600 - 9.0400	0.163⁽¹⁾
rs11967629	PSORS1C3	GG	23 (50%)	35 (49.3%)
		GA	23 (50%)	28 (39.44%)	0.8	0.3733 - 1.7145	0.467⁽²⁾
		AA	0 (0%)	8 (11.27%)	11.2535	0.6195 - 204.4117	0.002⁽¹⁾
+280	PSORS1C3	AA	40 (86.96%)	48 (67.61%)
+280	PSORS1C3	AG	6 (13.04%)	23 (32.39%)	3.1944	1.1850 - 8.6112	0.002⁽²⁾
rs11653893	CARD14	AA	14 (30.43%)	14 (19.72%)
		AG	18 (39.13%)	43 (60.56%)	2.3889	0.9494 - 6.0112	0.023⁽²⁾
		GG	14 (30.43%)	14 (19.72%)	1	0.3508 - 2.8510	1⁽¹⁾
rs189286068	CARD14	CC	43 (93.48%)	67 (93.37%)
rs189286068	CARD14	CT	3 (6.52%)	4 (6.63%)	0.8557	0.1825 - 4.0124	1⁽¹⁾
c.3150 p.T812A/S	CARD14	AA	45 (97.83%)	68(95.77%)
		AG	1 (2.17%)	2 (2.82%)	1.3235	0.1165 - 15.0318	0.683⁽¹⁾
		AT	0	1 (1.41%)	0.6618	0.0403 - 10.8535	0.497⁽¹⁾
rs11652075	CARD14	CC	14 (30.43%)	17 (23.94%)
		CT	18 (39.13%)	40 (56.33%)	1.8301	0.7441 - 4.5008	0.124⁽²⁾
		TT	14 (30.43%)	14 (19.72%)	0.8235	0.2957 - 2.2936	0.694⁽¹⁾
rs61757652	CARD14	CC	30 (65.22%)	54 (76.06%)
rs61757652	CARD14	CT	16 (34.78%)	17 (23.94%)	0.5903	0.2611 - 1.3344	0.121⁽¹⁾
rs1486223942	CARD14	CC	46 (100%)	69 (97.18%)
rs1486223942	CARD14	CT	0	2 (2.82%)	3.3453	0.1570 - 71.2792	0.246⁽¹⁾
c.3285+54	CARD14	CC	46 (100%)	68 (95.77%)
c.3285+54	CARD14	CG	0	3 (4.23%)	4.7518	0.2398 - 94.1681	0.121⁽¹⁾
rs376428578	CARD14	CC	12 (26.09%)	44 (61.97%)
rs376428578	CARD14	CA	34 (73.91%)	27 (38.03%)	0.2166	0.0960 - 0.4888	<0.001⁽²⁾
rs2149356	TLR4	TT	3 (6.52%)	6 (8.45%)
		TG	23 (50%)	30 (42.25%)	0.6522	0.1472 - 2.8897	0.781⁽²⁾
		GG	20 (43.48%)	35 (49.3%)	0.875	0.1970 - 3.8858	1⁽²⁾
c.331-428	TLR4	TT	32 (69.57%)	51 (71.83%)
c.331-428	TLR4	TG	14 (30.43%)	20 (28.17%)	0.8964	0.3973 - 2.0221	0.876⁽¹⁾
c.331-200	TLR4	GG	45 (97.83%)	68 (95.77%)
c.331-200	TLR4	GA	1 (2.17%)	3 (4.23%)	1.9853	0.2002 - 19.6899	0.683⁽¹⁾
c.331-102	TLR4	TT	45 (97.83%)	66 (92.96%)
c.331-102	TLR4	TA	1 (2.17%)	5 (7.04%)	3.4091	0.3853 - 30.1654	0.088⁽¹⁾
c.331-1	TLR4	GG	45 (97.83%)	68 (95.77%)
c.331-1	TLR4	GC	1 (2.17%)	3 (4.23%)	1.9853	0.2002 - 19.6899	0.683⁽¹⁾
rs770576183	TLR4	GG	46 (100%)	69 (97.18%)
		GC	0 (0%)	1 (1.41%)	2.0072	0.0800 - 50.3437	0.495⁽¹⁾
		GA	0 (0%)	1(1.41%)	2.0072	0.0800 - 50.3437	0.495⁽¹⁾
rs1018673641	TLR4	AA	44 (95.65%)	60 (84.5%)
rs1018673641	TLR4	AT	2 (4.35%)	11 (15.5%)	4.0333	0.8509 - 19.1187	0.008⁽¹⁾
c.371 p.L101 L	TLR4	CC	27 (58.7%)	41 (57.75%)
c.371 p.L101 L	TLR4	CT	19 (41.3%)	30 (42.25%)	1.0398	0.4899 - 2.2067	1⁽²⁾
c.376 p.S102S	TLR4	CC	20 (43.48%)	40 (56.34%)
c.376 p.S102S	TLR4	CT	26 (56.52%)	31 (43.66%)	0.5962	0.2821 - 1.2598	0.089⁽²⁾

SNPs in haplotype block	Haplotype	Controls (n=46)	Patients (n=71)	p-Value
PSORS1C3/rs11967629 and +280 G>A				4-df, P<0.001
	G-G	23 (50%)	35 (49.3%)
	GA-G	17 (36.96%)	7 (9.86%)	0.002
	A-G	0 (0%)	6 (8.45%)	0.007
	A-AG	0 (0%)	2 (2.82%)	0.243
	GA-GA	6 (13.04%)	21 (29.6%)	0.029
PSORS1C3/rs3130506 and rs3871246				5-df, P=0.057
	C-A	2 (4.35%)	7 (9.86%)
	CT-A	11 (23.91%)	18 (25.35%)	0.229
	CT-AG	13 (28.26%)	14 (19.72%)	0.07
	T-AG	12 (26.09%)	12 (16.9%)	0.063
	T-A	5 (10.87%)	7 (9.86%)	0.296
	T-G	3 (6.52%)	13 (18.3%)	1
PSORS1C3/rs3868542, rs11507945 and rs3871247				6-df, P=0.007
	A-C-C	18 (39.13%)	28 (39.44%)
	AG-C-CT	3 (6.52%)	5 (7.04%)	1
	G-C-T	2 (4.35%)	1 (1.41%)	0.361
	G-CT-T	2 (4.35%)	4 (5.63%)	0.739
	G-T-T	0 (0%)	8 (11.27%)	0.002
	AG-CT-CT	21 (45.65%)	24 (33.8%)	0.425
	A-CT-CT	0 (0%)	1 (1.41%)	1
CARD14/rs11653893/rs11652075/rs61757652				8-df, P<0.001
	A-C-C	8 (17.4%)	7 (9.86%)
	A-C-CT	6 (13.04%)	7 (9.86%)	0.774
	AG-C-C	0 (0%)	1 (1.41%)	0.393
	G-CT-C	0 (0%)	1 (1.41%)	0.393
	AG-T-C	0 (0%)	1 (1.41%)	0.393
	AG-C-CT	0 (0%)	2 (2.82%)	0.07
	AG-CT-C	8 (17.4%)	31 (43.67)	0.002
	AG-CT-CT	10 (21.74%)	8 (11.27%)	0.792
	G-T-C	14 (30.43%)	13 (18.3%)	1
TLR4/rs1018673641-c.371-c.376				5-df, P<0.001
	A-C-C	18 (39.13%)	39 (54.93%)
	A-T-C	2 (4.35%)	1 (1.41%)	0.163
	A-T-T	15 (32.6%)	18 (25.35%)	0.069
	A-C-T	9 (19.56%)	2 (2.82%)	<0.001
	T-C-T	1 (2.18%)	1 (1.41%)	0.572
	T-T-T	1 (2.18%)	10 (14.08%)	0.047

Brasil

Brasil

Association of PSORS1C3, CARD14 and TLR4 genotypes and haplotypes with psoriasis susceptibility

Abstract

Introduction

Material and Methods

Patients and control subjects

Sample size calculation and power of study

DNA sequencing of PSORS1C3, CARD14 and TLR4

Cytokine quantification

Data analysis

Statistical analysis

Results

Association between PSORS1C3, CARD14 and TLR4 gene polymorphisms and psoriasis

**Haplotype and linkage disequilibrium analysis of PSORS1C3, CARD14 and TLR4 variants**

Association between inflammatory cytokines and genotypes in psoriatic patients

Discussion

Acknowledgements

References

Internet Resources

Associate Editor:

Publication Dates

History