Single nucleotide polymorphism rs 2070874 at Interleukin-4 is associated with increased risk of type 1 diabetes mellitus independently of human leukocyte antigens

Awad E Osman; Imad Brema; Alaa AlQurashi; Abdullah Al-Jurayyan; Benjamin Bradley; Muaawia A Hamza

doi:10.1177/03946320221090330

. 2022 Apr 11;36:03946320221090330. doi: 10.1177/03946320221090330

Single nucleotide polymorphism rs 2070874 at Interleukin-4 is associated with increased risk of type 1 diabetes mellitus independently of human leukocyte antigens

Awad E Osman ^1,^✉, Imad Brema ², Alaa AlQurashi ³, Abdullah Al-Jurayyan ¹, Benjamin Bradley ⁴, Muaawia A Hamza ³

PMCID: PMC9006359 PMID: 35404688

Abstract

Introduction

Type 1 diabetes mellitus (T1DM) is characterized by autoimmune destruction of insulin-producing pancreatic beta (β-) cells. Previous studies suggested an imbalance between and pro- and anti-inflammatory cytokines exacerbates T1DM development.

Objectives

We aimed to test the hypothesis that patients with T1DM carry a higher frequency of regulatory genes associated with low levels of the anti-inflammatory cytokines interleukin-4 (IL-4), its receptor (IL-4R), and interleukin-10 (IL-10).

Methods

Accordingly, we compared frequencies of five different single nucleotide polymorphisms (SNPs) in T1DM patients and healthy controls who had been typed for HLA-DRB1, HLA-DQA1, and HLA-DQB1 genes.

Results

The frequencies of rs2070874 (IL-4) alleles C and T differed between T1DM patients and controls (^cp = 0.0065), as did their codominant (^cp = 0.026) and recessive (^cp = 0.015) models. Increased frequencies were observed in T1DM patients for HLA alleles: DRB1*03 (pc < 0.0013), DRB1*04 (^cp = 0.0169), DQA1*03 (^cp = 0.0222), DQA1*05 (^cp < 0.0006), DQB1*02 (^cp = 0.0005), and DQB1*06 (^cp < 0.0005). And lower frequencies were observed for: DRB1*07 (^cp = 0.0078), DRB1*11 (^cp = 0.0013), DRB1*13 (^cp < 0.0364), DRB1*15 (^cp < 0.0013), DQA1*01 (^cp < 0.0006), and DQA1*02 (^cp = 0.0348). Certain DRB1: DQA1: DQB1 haplotypes showed greater frequencies, including, 03:05:02 (p < 0.0001) and 04:03:03 (p = 0.0017), whereas others showed lower frequencies, including, 07:02:02 (p = 0.0032), 11:05:03 (p = 0.0007), and 15:01:06 (p = 0.0002). Stratification for the above HLA haplotypes with rs2070874 C/C exhibited no significant differences between T1DM patients overall and controls. However, when stratified for the vulnerable HLA haplotype (03:05:02/04:03:03), young patients in whom T1DM began at ≤13 years had a higher frequency of the SNP (rs2070874 C/C); a gene associated with low IL-4 production (p < 0.024).

Conclusion

This study suggests that possession of the rs2070874 C/C genotype, which is associated with low production of IL-4, increases the risk of T1DM in young individuals carrying vulnerable HLA alleles/haplotypes.

Keywords: Type 1 diabetes mellitus (T1DM); single nucleotide polymorphisms (SNPs); Interleukin-10; Interleukin-4; and Interleukin-4 receptor (IL-10, IL-4, IL-4R)

Introduction

Type 1 diabetes mellitus (T1DM) is a chronic disease characterized by autoimmune destruction of insulin-producing pancreatic beta cells (β-cells), leading to insulin deficiency.¹ Between 5% and 10% of all diabetes patients worldwide have T1DM, and the incidence is estimated to be approximately 3% annually with significant geographical variations²; the highest incidence being in Finland (40.2/100,000),³ and the lowest in China (0.1/100,000).⁴ In 2017, Saudi Arabia was ranked eighth worldwide regarding the numbers of TIDM patients and fourth in terms of the incidence rate of the disease, which was estimated to be (33.5 per 100,000 individuals) of TIDM.⁵

T1DM occurs more frequently in genetically susceptible individuals who are subject to various environmental and epigenetic factors, as indicated by the concordance rate of T1DM in monozygotic twins, ranging between 13% and 65%.^6,7 Importantly, in twins of patients with early onset of T1DM (<24 years) the probability of progression to T1DM was 38% compared to late-onset patients (>24 years) where the probability was 6% (Redondo et al. 2001)⁶; suggesting an inverse association between the burden of genetic risk and age of onset. This is accounted for by multiple genes, including those associated with peptide processing and regulation of inflammatory reactions being implicated in pathogenesis.

Self-reactive T cells are normally heavily suppressed to prevent autoimmunity. However, in T1DM, genetic predisposition carried by alleles within the human leukocyte antigen (HLA) region leads to a breakdown in peripheral tolerance and the progressive destruction of insulin-producing β-cells.⁸ In addition, genetic regulation of expression, function, and production of both pro-and anti-inflammatory cytokines plays a role in triggering the inflammatory β-cell destruction.^9-11 While the HLA-DRB1/DQA1/DQB1 genes on chromosome six encode cell surface molecules that determine which self-peptides are presented via T-cell receptors (TCRs), cytokines regulate the expansion or suppression of T-cell clones.^12,13 The interleukin-4 (IL-4) gene on chromosome five and the interleukin 10 (IL-10) gene on chromosome one encode cytokines that down-regulate inflammatory responses. However, decreased levels have been observed in both newly diagnosed T1DM patients and non-obese diabetic (NOD) mice thereby facilitating insulitis.^14,15 Conversely, genetic overexpression of IL-4 prevents insulitis and decreases the incidence of diabetes.¹⁶ Notwithstanding these findings, others have claimed to have refuted a role for IL-4 regulator genes (Riemsnider et al. 2000).¹⁷ IL-10 also generates feedback regulation of autoimmunity by binding to the IL-10 receptor (IL-10R) expressed on the surface of many immune cells.¹⁵

Multiple research studies, including our own, have investigated associations between single nucleotide polymorphisms (SNPs) linked to regulatory or structural regions of cytokine genes and T1DM.^18-21 Depending on their location within the genome, SNPs are flags highlighting possible differences in the expression, function, and/or production of cytokines within T1DM phenotypes. For example, the IL-4 SNP rs2070874 is located in the 5^′-untranslated region of exon one of the IL-4 gene and, as such, could regulate the levels of cytokine production. In addition, rs1800871 and rs1800872 are located in the promoter region of the IL-10 gene, influencing messenger RNA transcription and expression.²²

In this study, we hypothesized that in T1DM “Self-peptides” associated with β-cell are targeted by autoimmune T-cell clones, whose evolution is facilitated by an excess of pro-inflammatory cytokines (e.g., TNF-α) and/or a dearth of anti-inflammatory cytokines (e.g., IL-4 or IL-10); both scenarios facilitating β-cell destruction. Based on this hypothesis, we studied SNPs located within the IL-10 (rs1800896, rs1800871, and rs1800972), IL-4 (rs2070874), and IL-4R (rs1801275) genes in T1DM patients and controls typed for HLA - DRB1, DRA1, and DQB1 loci. Our objective was to identify significant differences in gene frequencies between patients, with age of onset above and below 13, and controls.

Materials and methods

This case-controlled cohort study of 371 individuals included 180 patients diagnosed with T1DM and 191 healthy controls. The sample size calculation was performed based on a descriptive epidemiological study on the Saudi population by Robert et al. utilizing Fisher’s exact test at a level of 5% and power of 80. Patients were diagnosed according to the American Diabetes Association criteria.²³ We included individuals of Saudi origin (patients and controls) and only patients who were less than 30 years of age at the time of blood collection. Exclusion criteria included non-Saudi patients, patients with type 2 diabetes, young patients with maturity-onset diabetes, patients with other forms of secondary diabetes, and immunocompromised patients. The healthy unrelated control group was selected randomly from the list of bone marrow transplant (BMT) donors of King Fahad Medical City (KFMC) Hospital who had no history of diabetes or other autoimmune diseases.

Guidelines of the Helsinki Declaration on Human Experimentation were implemented, and the Institutional Review Board (IRB) at KFMC approved the study. An exemption from obtaining informed consent from patients was also approved by the IRB because we used clinical samples collected from patients for hemoglobin A1c or archived DNA of BMT donors. Peripheral blood sample were collected into EDTA tubes between January 2016 and December 2019 for T1DM patients and from February 2015 to July 2020 for healthy controls. Blood samples integrity was assessed for quality purposes at the time of collection. All procedures adhered to rules and regulations of the Saudi government, the KFMC/IRB policies and procedures, and the IHC Good Clinical Practice guidelines.

A MagNa Pure Compact instrument (Roche Diagnostics GmbH, Roche Applied Science, Mannheim, Germany) was used to extract genomic DNA according to the manufacturer’s instructions, and a minimum of 20 ng/μl of DNA with 260/280 nm values between 1.6 and 2.0 was set as the standard for performing the genotype assays.

Five SNPs, including rs2070874 (IL-4), rs1800896 (IL-10), rs1800871 (IL-10), rs1800872 (IL-10), and rs1801275 (IL-4R), were investigated (Table 1). A PCR-based assay, which included sequence-specific forward and reverse primers with two TaqMan® MGB probes and dyes (VIC™ and FAM™), was used for genotyping procedures according to the manufacturer’s instructions (Applied Biosystems, Foster City, CA).

Table 1.

Selected SNPs for IL-10, IL-4, and IL-4R genes (https://www.snpedia.com).

SNP ID	Reference	Gene name	Chromosome location	Alleles	GMAF*
rs2070874	[18]	Interleukin-4 (IL-4)	5q31.1 (5^′UTR)	C>T	0.4279
rs1800896	[27]	Interleukin-10 (IL-10)	1q32.1 (intergenic/intragenic)	A>G	0.3026
rs1800871	[27]	Interleukin-10 (IL-10)	1q32.1 (intron)	G>A	0.4086
rs1800872	[27]	Interleukin-10 (IL-10)	1q32.1 (intron)	A>C	0.4091
rs1801275	[18]	Interleukin-4 receptor (IL-4R)	16p12.1 (intron)	A>G	0.3453

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*Global Minor Allele Frequency (GMAF) is frequency of the minor allele as reported in a default global population.

For HLA genotyping, we used a sequence-specific oligonucleotide probe (SSOP) utilizing a Luminex-based method (One Lambda, San Diego, USA) to detect the HLA-DRB1, HLA-DQA1, and HLA-DQB1 genes according to the manufacturer’s instructions (http://www.onelambda.com). The HLA genotyping procedure performed in our laboratory is continuously monitored for quality assurance by the College of American Pathologists (CAP).

Statistical analysis

Hardy-Weinberg equilibrium (HWE) for expected and observed allele frequencies for control data was assessed based on the χ² distribution (degree of freedom = 1).²⁴ For each SNP allele, allele frequencies and genotype models (codominant, dominant, and recessive) were derived by an algorithm based on the direct counting method utilizing SNPStats software (https://www.snpstats.net/start.htm).

Dominance is defined as the relationship between the two alleles of one gene, where the effect of the first allele (dominant) in the phenotype masks the contribution of the second allele (recessive).²⁵

Codominance is defined as a form of dominance in which two different heterozygous alleles of one gene are fully expressed, and the offspring’s phenotype is neither dominant nor recessive.²⁶

D^′ statistic and p-value tests were implemented to analyze the linkage disequilibrium (LD) between the SNPs. The D^′ LD measurement ranged from 0 (no LD) to 1 (strong LD), and significant differences were indicated by a p-value less than 5%.²⁷ Fisher’s exact test and the log of the odds (logit) for the presence of each SNP were used to specify the significant differences between patients and controls at an overall level of p < 0.05. HLA alleles, haplotype frequencies, and stratification with SNPs were conducted using SPSS software version 22.0. The Bonferroni correction test was used whenever it was necessary to correct multiple comparisons, and the results are presented as corrected p (^cp) values.

Results

Of 180 patients with T1DM, 90 (50%) were females (aged 3–28) and 90 (50%) were males (aged 16–30). The age of onset of T1DM was below 13 years in 142 (78.9%) and above 13 in 34 (18.1%) patients. In four males date of onset was unavailable. Of 191 healthy controls, 95 were female aged 1–76 and 96 males aged 1–79 (Table 2).

Table 2.

Demographic and clinical data for T1DM patients and Controls.

	Sex	T1DM patients (no. = 180)			Controls (no. = 191)
	Sex	All patients (no. = 180)	Onset <13 years (no. = 142)	Onset ≥13 years (no. = 34)	Controls (no. = 191)
Totals	Females	90	75	15	95
Totals	Male	90	67*	19*	96
Age range (yrs.)	Female	3–28	1–12	13–27	1–76
Age range (yrs.)	Male	16–30	0.8–12	13–32	1–79
Age median (yrs.)	Female	15.2	9.0	15.0	25
Age median (yrs.)	Male	22.7	8.0	15.0	25
Onset of T1DM (mean yrs.)	Female	9.7	8.0	16.3
Onset of T1DM (mean yrs.)	Male	8.6	7.0	17.2
Duration of T1DM (mean yrs.)	Female	9.7	9.9	8.7
Duration of T1DM (mean yrs.)	Male	8.9	8.7	8.4

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*In four cases date of onset was unavailable.

Single nucleotide polymorphisms

Conformation to HWE was observed for the three SNPs, rs1800871, rs1800872, and rs1801275 with expected statistical values (p > 0.05); however, two SNPs, rs2070874 and rs1800896, did not conform to HWE (p < 0.05). Among the five SNPs tested for possible LD, only rs1800896 and rs1800872 showed significant statistical values (D^′ = 0.9993 and p < 0.001) and were considered to exhibit high LD. No other significant values for LD were detected.

The allele frequencies and genotype models for SNPs in patients and controls are shown in Table 3. Only rs2070874 SNP (IL4) showed significant differences in terms of alleles (^cp < 0.0065), and codominant (^cp < 0.026) and recessive (^cp < 0.0105) genotype model frequencies furthermore these differences remained significant after Bonferroni correction.

Table 3.

Association between SNPs and susceptibility to T1DM.

SNP ID	SNP model	Genotype	T1DM (total alleles = 360)	Controls (total alleles = 382)	OR (95% CI)	p-value	Corrected ^cp value
rs2070874 (IL-4)	Alleles	C	308 (85.6%)	291 (79%)	1.8 (1.3, 2.7)	0.0013	0.0065
	Alleles	T*	52 (14.4%)	91 (21%)	1.8 (1.3, 2.7)	0.0013	0.0065
	Codominant	C/C	131 (72.8%)	116 (60.7%)	1.0	1.0
		C/T	46 (25.6%)	59 (30.9%)	1.4 (0.9, 2.3)	0.1
		T/T	3 (1.7%)	16 (8.4)%	6.0 (1.7, 21.2)	0.0052	0.026
	Dominant	C/C versus C/T+T/T			1.7 (1.7, 21.5)	0.23
	Recessive	C/C+C/T versus T/T			5.4 (1.5, 18)	0.0021	0.015
rs1800896 (IL-10)	Alleles	T	215 (60%)	240 (62%)	0.9 (0.7, 1.2)	0.64
	Alleles	C*	145 (40%)	144 (38%)	0.9 (0.7, 1.2)	0.64
	Codominant	T/T	65 (36.1%)	81 (43.2%)	1.0	1.0
		T/C	85 (47.2%)	75 (39.9%)	0.7 (0.5, 1.1)	0.13
		C/C	30 (16.7%)	32 (17%)	0.9 (0.5,1.8)	0.8
	Dominant	T/T versus T/C+C/C			0.8 (0.5, 1.6)	0.6
	Recessive	T/T+T/C versus C/C			1.1 (0.6, 1.7)	0.9
rs1800871(IL-10)	Alleles	G	290 (81%)	156 (82%)	1.5 (1.1, 2.1)	0.033	0.165
	Alleles	A*	70 (19%)	34 (18%)	1.5 (1.1, 2.1)	0.033	0.165
	Codominant	G/G	110 (61.1%)	102 (54.3%)	1.0	1.0
		G/A	70 (38.9%)	73 (38.8%)	1.2 (0.7,1.7)	0.5
		A/A	0%	13 (6.9%)	1.0	1.0
	Dominant	G/G versus A/G+G/G			1.3 (0.9, 2.0)	0.18
	Recessive	G/G+A/G versus A/A			1.0	1.0
rs1800872 (IL-10)	Alleles	G	264 (73%)	267 (70%)	1.2 (0.9, 1.6)	0.3
	Alleles	T*	96 (27%)	115 (30%)	1.2 (0.9, 1.6)	0.3
	Codominant	G/G	97 (53%)	90 (48.1%)	1.0	1.0
		T/G	70 (38.9%)	82 (43.9%)	1.3 (0.8, 1.9)	0.2
		T/T	13 (7.2%)	15 (8%)	1.2 (0.6, 2.8)	0.4
	Dominant	G/G versus T/G+T/T			1.3 (0.8, 1.9)	0.3
	Recessive	G/G+T/G versus T/T			1.1 (0.5, 2.4)	0.8
rs1801275 (IL-4R)	Alleles	A	286 (79%)	274 (74%)	1.4 (0.9,1.9)	0.08
	Alleles	G*	74 (21%)	96 (26%)	1.4 (0.9,1.9)	0.08
	Codominant	A/A	114 (63.3%)	100 (55.2%)	1.0	1.0
		A/G	58 (32.2%)	66 (36.5%)	1.3 (0.8, 2.0)	0.2
		G/G	8 (4.4%)	15 (8.3%)	2.1 (0.8, 5.2)	0.1
	Dominant	A/A versus A/G+G/G			1.4 (0.9, 2.4)	0.12
	Recessive	A/A+A/G versus G/G			1.9 (0.8, 4.7)	0.13

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*The second most common allele occurring in the population.

The allele frequency for rs1800871 (IL-10) exhibited significant variation that did not remain after Bonferroni correction. No other differences were found, and interaction analysis for these SNPs revealed no difference between males and females.

HLA-DRB1

Thirteen alleles for DRB1 were detected (Table 4), and DRB1*03 (^cp = 0.0013) and DRB1*04 (^cp = 0.0169) were observed at higher frequencies in patients than in controls, representing a total of 249 (71.5%) out of 348 DRB1 alleles among T1DM patients. In contrast, DRB1*07 (^cp = 0.0078), DRB1*11 (^cp = 0.0013), DRB1*13 (^cp = 0.0364), and DRB*15 (^cp = 0.0013) were at greater frequencies in healthy controls with a total of 200 (52.3%) out of 382 alleles among the control samples. None of the remaining alleles differed between T1DM and controls.

Table 4.

Frequency distribution and association of HLA-DRB1 alleles in T1DM and controls.

DRB1	T1DM (n = 348)	Controls (n = 382)	OR (95%CI)	p Value	^cp value
*01	8 (2.3)	14 (3.7)	0.5 (0.2–1.3)	0.1624
*03	142 (40.8)	56 (14.7)	4.0 (2.8–5.7)	0.0001	0.0013
*04	107 (30.7)	78 (20.4)	1.7 (1.2–2.4)	0.0013	0.0169
*07	38 (10.9)	78 (20.4)	0.5 (0.3–0.7)	0.0006	0.0078
*08	2 (0.6)	5 (1.3)	n/a	n/a	n/a
*09	2 (0.6)	2 (0.5)	n/a	n/a	n/a
*10	6 (1.7)	10 (2.6)	n/a	n/a	n/a
*11	5 (1.4)	34 (8.9)	0.2 (0.06–0.4)	0.0001	0.0013
*12	n/a	1 (0.3)	n/a	n/a	n/a
*13	24 (6.9)	53 (13.9)	0.5 (0.3–0.8)	0.0028	0.0364
*14	1 (0.3)	5 (1.3)	n/a	n/a	n/a
*15	4 (1.2)	36 (9.4)	0.1 (0.04–0.3)	<0.0001	<0.0013
*16	9 (2.6)	10 (2.6)	n/a	n/a	n/a

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HLA-DQA1

Six alleles for DQA1 were observed (Table 5). DQA1*03 (^cp = 0.0222) and DQA1*05 (^cp = 0.0006) were present at higher frequencies in T1DM patients, whereas DQA1*01 (^cp = 0.0006) and DQA1*02 (^cp = 0.0348) were found at higher frequencies in healthy controls. DQA1*04 and DQA1*06 did not differ between the two groups.

Table 5.

Frequency distribution and association of HLA-DQA1 alleles in T1DM and controls.

DQA1	T1DM (n = 358)	Controls (n = 370)	OR (95%CI)	p Value	^cp value
*01	58 (16.2)	132 (35.7)	0.3 (0.2–0.5)	0.0001	0.0006
*02	46 (12.8)	76 (20.5)	0.6 (0.4–0.8)	0.0058	0.0348
*03	106 (29.6)	75 (20.3)	1.7 (1.2–2.3)	0.0037	0.0222
*04	2 (0.6)	2 (0.5)	n/a	n/a	n/a
*05	146 (40.8)	84 (22.7)	2.3 (1.7–3.2)	0.0001	0.0006
*06	0	1 (0.03)	n/a	n/a	n/a

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HLA-DQB1

Five alleles for DQB1 were detected (Table 6). DQB1*02 was increased in frequency in T1DM patients compared with healthy controls (^cp = 0.0005), whereas DQB1*06 was found more frequently in controls (^cp = 0.0005). HLA-DQB1*05 did not reach significance after the Bonferroni correction, whereas DQB1*03 and DQB1*04 did not show any differences.

Table 6.

Frequency distribution and association of HLA-DQB1 alleles in T1DM and controls.

DQB1	T1DM (n = 358)	Controls (n = 382)	OR (95%CI)	p Value	^cp value
*02	183 (51.1)	127 (33.3)	2.1 (1.6–2.8)	<0.0001	<0.0005
*03	111 (31)	110 (28.8)	0.9 (0.7–1.2)	0.5	n/a
*04	4 (1.1)	7 (1.8)	n/a	n/a	n/a
*05	31 (8.7)	54 (14.1)	0.6 (0.4–0.9)	0.0268	n/a
*06	29 (8.1)	84 (22.0)	0.3 (0.2–0.5)	<0.0001	<0.0005

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HLA-DRB1:DQA1: DQB1 haplotypes

Fifty-one different haplotypes for DRB1:DQA1: DQB1 were observed (Table 7), but only five exhibited frequencies greater than 5% and differed between patients and controls. Specifically, 03:05:02 (p < 0.0001) and 04:03:03 (p = 0.0017) exhibited greater frequencies in patients compared with controls; whereas 07:02:02 (p = 0.0032), 11:05:03 (p = 0.0007) and 15:01:06 (p = 0.0002) were higher in healthy controls.

Table 7.

Frequency distribution and association of DRB1: DQA1: DQB1 haplotypes in T1DM and controls.

Haplotype	Case (n = 344)	CON (n = 342)	OR (95%CI)	p Value
3.05.02	134 (40.2)	46 (13.5)	4.1 (2.8114–5.9967)	<0.0001
4.03.03	94 (28.3)	59 (17.3)	1.8 (1.2491–2.6040)	0.0017
7.02.02	32 (9.6)	58 (17)	0.5 (0.3157–0.7932)	0.0032
1.01.05	7 (2.1)	15 (4.4)
13.01.06	22 (6.6)	35 (10.2)	0.6 (0.3438–1.0447)	0.0709
10.01.05	6 (1.8)	10 (2.9)
15.01.05	9 (2.7)	2 (0.6)
11.05.03	3 (0.9)	23 (6.7)	0.1 (0.0363–0.4103)	0.0007
15.01.06	3 (0.9)	28 (8.2)	0.1 (0.0299–0.3298)	0.0002
4.03.02	6 (1.8)	4 (1.2)
Other	17 (5.1)	63 (18.3)

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Stratification by SNP and HLA-DRB1 genotype

According to previously published studies,^28-31 we classified T1DM subjects and controls according to genotype models based on the presence or absence of DRB1*03/04 or DRB1*07/13, and presence or absence of rs2070874 C/C. We report that after controlling for HLA the rs2070874 C/C association with T1DM risk was no longer significant (Table 8).

Table 8.

Stratification rs2070874 C/C genotype with HLA- DRB1.

Genotype models¹			T1DM no. (%)	Controls no. (%)	OR (95%CI); p value
DRB1*03/04	DRB1*07/13	Rs2070874 C/C	T1DM no. (%)	Controls no. (%)	OR (95%CI); p value
+	-	+	86 (72.9%)	44 (62.9%)	1.2 (0.7, 1.9); 0.5
+	-	-	32 (27.1%)	26 (37.1%)	1.2 (0.7, 1.9); 0.5
-	+	+	8 (61.5%)	38 (63.3%)	0.9 (0.3, 3.2); 0.9
-	+	-	5 (38.5%)	22 (36.7%)	0.9 (0.3, 3.2); 0.9
Totals			131	130

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¹DRB1*03 or DRB1*04 with DRB1*07 or DRB1*13 individuals were excluded.

However, when we divided patients into two groups, based on the age of onset of T1DM,³² we demonstrated a significant increase in the frequency of rs2070874 C/C in patients with onset age ≤13 years (p ≤ 0.0027), and no increase in patients with onset >13 years (Table 9).

Table 9.

Stratification of rs2070874 C/C genotypes with HLA - DRB1 by age of onset of T1DM.

Age of onset. (yrs.)	Genotype models¹			T1DM no. (%)	Controls. No. (%)	OR (95%CI); p value
Age of onset. (yrs.)	DRB1*03/04	DRB1*07/13	rs2070874 C/C	T1DM no. (%)	Controls. No. (%)	OR (95%CI); p value
>13	+	-	+	77 (78.6%)	44 (62.9%)	2.2 (1.1, 4.3); 0.027
	+	-	-	21 (21.4%)	26 (37.1%)	2.2 (1.1, 4.3); 0.027
	-	+	+	6 (66.7%)	38 (63.3%)	1.2 (0.3, 5.1); 1.2
	-	+	-	3 (33.3)	22 (36.7%)	1.2 (0.3, 5.1); 1.2
Totals				107	130
≤13	+	-	+	9 (45%)	44 (62.9%)	0.5 (0.2,1.3); 0.2
	+	-	-	11 (55%)	26 (37.1%)	0.5 (0.2,1.3); 0.2
	-	+	+	2 (50%)	38 (63.3%)	0.6 (0.1, 4.4); 0.6
	-	+	-	2 (50%)	22 (36.7%)	0.6 (0.1, 4.4); 0.6
Totals				24	130

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¹DRB1*03 or DRB1*04 with DRB1*07 or DRB1*13 individuals were excluded.

Stratification by SNP and HLA-DRB: DQA1:DQB1 haplotype

We classified T1DM subjects and controls according to genotype models based on the presence or absence of HLA-DRB: DQA1:DQB1 haplotypes, and the presence or absence of the rs2070874 C/C genes and found no significant differences between cohorts overall (p = 0.09). See Table 10 for details.

Table 10.

Stratification of rs2070874 C/C genotype with HLA - DRB1: DQA1; DQB1 haplotypes.

Genotype model (DRB1: DQA1: DQB1 and SNP)¹			T1DM. No. (%)	Controls. No. (%)	OR (95%CI); p value
03:05:02/04:03:03	07:02:02/11:05:03	rs2070874 C/C	T1DM. No. (%)	Controls. No. (%)	OR (95%CI); p value
+	-	+	98 (74.8%)	43 (63.2%)	1.7 (0.9, 3.2); 0.09
+	-	-	33 (25.2%)	25 (36.8%)	1.7 (0.9, 3.2); 0.09
-	+	+	7 (58.3%)	31 (67.4%)	0.7 (0.2, 2.5); 0.6
-	+	-	5 (41.7%)	15 (32.6%)	0.7 (0.2, 2.5); 0.6
Totals			143	114

Open in a new tab

¹DRB103:05:02 or 04:03:03 with 07:02:02 or 11:05:03 DRB1 individuals were excluded.

However, further stratification based on the date of onset of T1DM showed patients with early-onset disease (≤13 years) had a greater frequency of the genotype, 03:05:02/04:03:03; rs2070874 C/C, (p ≤ 0.024). There was no difference between the groups for the presumed protective genotypes, 07: 02:02/11: 05:03 who carried rs2070874 C/C (Table 11).

Table 11.

Stratification of rs2070874 C/C with HLA - DRB1: DQA1; DQB1 haplotypes, according to age of onset of T1DM.

Age of onset (yrs.)	Genotype models¹			T1DM no.(%)	Controls. No. (%)	OR (95%CI); p value
Age of onset (yrs.)	03:05:02/04:03:03	07:02:02/11:05:03	rs2070874 C/C	T1DM no.(%)	Controls. No. (%)	OR (95%CI); p value
≤13	+	-	+	83 (79%)	43 (63.2%)	2.2 (1.1, 4.3); 0.024
	+	-	-	22 (21%)	25 (36.8%)	2.2 (1.1, 4.3); 0.024
	-	+	+	5 (71.4%)	31 (67.4%)	1.2 (0.2, 6.7); 0.8
	-	+	-	2 (28.6%)	15 (32.6%)	1.2 (0.2, 6.7); 0.8
Totals				112	114
>13	+	-	+	15 (55.6%)	43 (63.2%)	0.7 (0.3, 1.8); 0.7
	+	-	-	12 (44.4%)	25 (36.8%)	0.7 (0.3, 1.8); 0.7
	-	+	+	1 (25%)	31 (67.4%)	0.2 (0.02, 1.7); 0.12
	-	+	-	3 (75%)	15 (32.6%)	0.2 (0.02, 1.7); 0.12
Totals				31	114

Open in a new tab

¹DRB103:05:02 or 04:03:03 with 07:02:02 or 11:05:03 DRB1 individuals were excluded.

Discussion

Our findings indicate genes associated with low production of IL-4 facilitate the early onset of T1DM in individuals with vulnerable HLA genotypes. The association between HLA and T1DM has been extensively studied, but the involvement of IL-4 has been unclear; and whereas low IL-4 was implicated in NOD mice (Shoda et al. 2004)³³ and patients with T1DM (Hagar and Zohreh 2016),³⁴ others claimed to have disproved a role for IL-4 regulatory genes (Reimsnider et al. 2000).¹⁷ But no account was taken of the age of onset of T1DM in their analysis. Our data are consistent with and add to, the observation that early-onset T1DM is associated with a higher twin-concordance rate in younger patients due to an increased burden of non-HLA genes controlling B and T-cell development (Inshaw et al. 2020, Redondo et al., 2001and 2020).^35,36

The well-established role of HLA Class II molecules is to process peptides external to the cell surface and present them to T-helper cells to generate an immune response, or to T-regulator cells to generate tolerance. In this context, our data imply the HLA haplotype most strongly associated with T1DM (03:05:02/04:03:03) presents a unique array of β-cell derived self-peptides to T-helper cells triggering autoimmunity. Conversely, the HLA haplotype most strongly associated with protection against T1DM (07:02:02/11:05:03) produces β-cell self-peptides triggering tolerance. Thus immunity, or tolerance, to β-cell peptides is dictated initially by the HLA haplotype, and subsequent evolution of responses is directed by pro or anti-inflammatory cytokines.

Within the context of the simplistic paradigm whereby autoimmune diseases are facilitated by an imbalance between anti-inflammatory (IL-4, IL-10, IL-13) and pro-inflammatory cytokines (TNF- α, IFN- γ) low levels of the former and high levels of the latter facilitate T1DM onset (Moudgil and Chouby 2011)³⁹. Both our former finding (Osman et al. 2021),³⁷ that T1DM was associated with high TNF producer genes (rs361525), and current findings of low IL-4 producer genes are consistent with this model.

As demonstrated by next-generation genotyping array technology, several other genes are associated with aggressive early-onset T1DM in children under 7 years.³⁶ These include genes expressed in β-cells (GLIS3) and others affecting immune function via B-cell, T-cell, and Thymus development (IL2-RA, IL-10, IKZF3, THEMIS, CTSH). In Inshaw et al.’s study SNPs detecting IL-10 differed from those in ours and may account for our negative finding of an association between T1DM and IL-10. Furthermore, no SNPs linked to IL-4 and IL-4R, in particular the rs2070874, were used in their study. Hence, our results are concordant with their observation that the number of susceptibility genes is inversely correlated with the age of onset of T1DM.

Selection of controls in our study deserves comment in so far as bone marrow volunteer donors are selected for health and absence of autoimmune diseases; a feature that may have increased the differences between them and patients. Furthermore, they were not strictly matched for age range; the T1DM patients being 3–30 and controls ranging from 1 to 79 years. These differences may have introduced artefacts into the comparison between the groups and be addressed in future studies with larger numbers designed to take account of the entire age range of disease onset. Such studies will allow cumulative effects of susceptibility genes to be compared between the young and elderly. The ultimate application of this work is to develop early prophylactic screening of vulnerable individuals allowing intervention designed to arrest disease progression.

Conclusions

In this study, young T1DM patients (age of onset ≤13 years old) carrying vulnerable HLA genes had a higher frequency of the IL-4 “low producer” linked SNP rs2070874 C/C, consistent with the view that low levels of anti-inflammatory cytokines facilitate autoimmunity to β-cells.

Acknowledgements

This study is fully supported by King Fahad Medical City, Riyadh, Saudi Arabia. The authors would like to thank the patients and BMT donors who participated in this study.

Footnotes

Author’s Contribution: AO and MH designed the study. IB provided clinical information, and A AlQurashi and A Al-Jurayyan acquired information. AO and A Al-Jurayyan supervised laboratory work. AO and BB interpreted the data. AO drafted the manuscript. AO, BB, and IB revised the manuscript. BB supervised the manuscript and critically added comments.

Declaration of conflicting interests: The author(s) declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.

Funding: This study was completely funded by King Fahad Medical City.

Ethics approval: Ethical approval for this study was obtained from Institutional Review Board (IRB) at King Fahad Medical City, Riyadh, Saudi Arabia (IRB Log No: 16–054)

Informed consent: Informed consent was not sought for the present study because we used leftover clinical blood specimens in this project and approval from our IRB was obtained.

ORCID iD

Awad E Osman https://orcid.org/0000-0003-1945-4363

References

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2.Patterson CC, Dahlquist G, Soltész G, Green A. (2001) Is childhood-onset type I diabetes a wealth-related disease? An ecological analysis of European incidence rates. Diabetologia 44: B9–B16. [DOI] [PubMed] [Google Scholar]
3.Kaprio J, Tuomilehto J, Koskenvuo M, et al. (1992) Concordance for Type 1 (insulin-dependent) and Type 2 (non-insulin-dependent) diabetes mellitus in a population-based cohort of twins in Finland. Diabetologia 35(11): 1060–1067. [DOI] [PubMed] [Google Scholar]
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14.Kent SC, Chen Y, Clemmings SM, et al. (2005) Loss of IL-4 Secretion from Human Type 1a Diabetic Pancreatic Draining Lymph Node NKT Cells. Journal of immunology 175(7): 4458–4464. [DOI] [PubMed] [Google Scholar]
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16.Cameron MJ, Arreaza GA, Zucker P, et al. (1997) IL-4 prevents insulitis and insulin-dependent diabetes mellitus in nonobese diabetic mice by potentiation of regulatory T helper-2 cell function. Journal of immunology 159(10): 4686–4692. [PubMed] [Google Scholar]
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21.Osman AE, Brema I, AlQurashi A, Al-Jurayyan A, Bradley B, Hamza MA. (2021) Association of single-nucleotide polymorphisms in tumour necrosis factor and human leukocyte antigens genes with type 1 diabetes. International Journal of Immunogenetics 48(4): 326–335. [DOI] [PubMed] [Google Scholar]
22.Ding Q, Shi Y, Fan B, et al. (2013) The Interleukin-10 Promoter Polymorphism rs1800872 (-592C>A), Contributes to Cancer Susceptibility: Meta-Analysis of 16 785 Cases and 19 713 Controls. PLoS One 8(2): e57246. [DOI] [PMC free article] [PubMed] [Google Scholar]
23.American Diabetes Association; . 2. Classification and diagnosis of diabetes: Standards of medical care in diabetes-2021. Diabetes Care, 44. 2021;S15. [DOI] [PubMed] [Google Scholar]
24.Rodriguez S, Gaunt TR, Day INM. (2009) Hardy-Weinberg equilibrium testing of biological ascertainment for Mendelian randomization studies. American Journal of Epidemiology 169(4): 505–514. [DOI] [PMC free article] [PubMed] [Google Scholar]
25.New Oxford American Dictionary (2013) Choice Rev Online. [Google Scholar]
26.Banerjee AK, Guo W, Huang Y. (2019) Genetic and Epigenetic Regulation of Phenotypic Variation in Invasive Plants - Linking Research Trends towards a Unified Framework. NeoBiota. [Google Scholar]
27.Li MX, Yeung JMY, Cherny SS, Sham PC. (2012) Evaluating the effective numbers of independent tests and significant p-value thresholds in commercial genotyping arrays and public imputation reference datasets. Human Genetics 131(5): 747–756. [DOI] [PMC free article] [PubMed] [Google Scholar]
28.Brown JJ, Ollier WER, Thomson W, et al. (2006) TNF-α SNP Haplotype Frequencies in Equidae. Tissue Antigens. [DOI] [PubMed] [Google Scholar]
29.Osman AE, Eltayeb-ELSheikh N, Mubasher M, et al. (2016) Investigation of activating and inhibitory killer cell immunoglobulin-like receptors and their putative ligands in type 1 diabetes (T1D). Human Immunology 77(1): 110–114. [DOI] [PubMed] [Google Scholar]
30.Mehers KL, Long AE, Van Der Slik AR, et al. (2011) An Increased Frequency of NK Cell Receptor and HLA-C Group 1 Combinations in Early-Onset Type 1 Diabetes. Diabetologia. [DOI] [PubMed] [Google Scholar]
31.Van der Slik AR, Koeleman BPC, Verduijn W, Bruining GJ, Roep BO, Giphart MJ. (2003) KIR in type 1 diabetes: Disparate distribution of activating and inhibitory natural killer cell receptors in patients versus HLA-matched control subjects. Diabetes 52(10): 2639–2642. [DOI] [PubMed] [Google Scholar]
32.Al-Fifi SH. (2010) The relation of age to the severity of Type I diabetes in children. Journal of family & community medicine 17(2): 87–90. [DOI] [PMC free article] [PubMed] [Google Scholar]
33.Shoda LKM, Young DL, Ramanujan S, et al. (2005) A comprehensive review of interventions in the NOD mouse and implications for translation. Immunity 23(2): 115–126. [DOI] [PubMed] [Google Scholar]
34.Vaseghi H, Jadali Z. (2016) Th1/Th2 Cytokines in Type 1 Diabetes: Relation to Duration of Disease and Gender. Indian J Endocrinol Metab. [DOI] [PMC free article] [PubMed] [Google Scholar]
35.Inshaw JRJ, Cutler AJ, Crouch DJM, Wicker LS, Todd JA. (2020) Genetic variants predisposing most strongly to type 1 diabetes diagnosed under age 7 years lie near candidate genes that function in the immune system and in pancreatic B-cells. Diabetes Care 43(1): 169–177. [DOI] [PMC free article] [PubMed] [Google Scholar]
36.Redondo MJ, Concannon P. (2020) Genetics of type 1 diabetes comes of age. Diabetes Care 43(1): 16–18. [DOI] [PMC free article] [PubMed] [Google Scholar]
37.Elsid Osman A, Brema I, AlQurashi A, Al-Jurayyan A, Benjamin Bradley MAH. (2021) Association of single-nucleotide polymorphisms in tumour necrosis factor and human leukocyte antigens genes with type 1 diabetes. International Journal of Immunogenetics 48(4): 326–335. [DOI] [PubMed] [Google Scholar]

[bibr1-03946320221090330] 1.Roep BO, Thomaidou S, van Tienhoven R, Zaldumbide A. (2021) Type 1 diabetes mellitus as a disease of the β-cell (do not blame the immune system?). Nature Reviews Endocrinology 17: 150–161. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr2-03946320221090330] 2.Patterson CC, Dahlquist G, Soltész G, Green A. (2001) Is childhood-onset type I diabetes a wealth-related disease? An ecological analysis of European incidence rates. Diabetologia 44: B9–B16. [DOI] [PubMed] [Google Scholar]

[bibr3-03946320221090330] 3.Kaprio J, Tuomilehto J, Koskenvuo M, et al. (1992) Concordance for Type 1 (insulin-dependent) and Type 2 (non-insulin-dependent) diabetes mellitus in a population-based cohort of twins in Finland. Diabetologia 35(11): 1060–1067. [DOI] [PubMed] [Google Scholar]

[bibr4-03946320221090330] 4.Karvonen M, Viik-Kajander M, Moltchanova E, Libman I, LaPorte R, Tuomilehto J. (2000) Incidence of childhood type 1 diabetes worldwide. Diabetes Mondiale (DiaMond) Project Group. Diabetes Care 23(10): 1516–1526. [DOI] [PubMed] [Google Scholar]

[bibr5-03946320221090330] 5.Robert AA, Al-Dawish A, Mujammami M, Dawish MAA. (2018) Type 1 Diabetes Mellitus in Saudi Arabia: A Soaring Epidemic. International Journal of Pediatrics 2018: 9408370. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr6-03946320221090330] 6.Redondo MJ, Jeffrey J, Fain PR, Eisenbarth GS, Orban T. (2008) Concordance for Islet Autoimmunity among Monozygotic Twins. The New England Journal of Medicine 359(26): 2849–2850. [DOI] [PubMed] [Google Scholar]

[bibr7-03946320221090330] 7.Törn C, Hadley D, Lee HS, et al. (2015) Role of type 1 diabetes- Associated snps on risk of autoantibody positivity in the TEDDY study. Diabetes. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr8-03946320221090330] 8.Singh GC, Ahmed M, Zaid M, Hasnain S. (2020) Biochemical, serological, and genetic aspects related to gene HLA-DQB1 and its association with type 1 diabetes mellitus (T1DM). Molecular Genetics and Genomic Medicine 8(5): e1147. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr9-03946320221090330] 9.Jeker LT, Bour-Jordan H, Bluestone JA. (2012) Breakdown in peripheral tolerance in type 1 diabetes in mice and humans. Cold Spring Harbor perspectives in medicine 2(3): a007807. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr10-03946320221090330] 10.Lu J, Liu J, Li L, Lan Y, Liang Y. (2020) Cytokines in type 1 diabetes: mechanisms of action and immunotherapeutic targets. Clinical and Translational Immunology, 9(3): e1122. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr11-03946320221090330] 11.Redondo MJ, Steck AK, Pugliese A. (2018) Genetics of type 1 diabetes. Pediatric Diabetes 19(3): 346–353. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr12-03946320221090330] 12.Purcell AW, Croft NP, Tscharke DC. (2016) Immunology by numbers: Quantitation of antigen presentation completes the quantitative milieu of systems immunology. Current Opinion in Immunology 40: 88–95. [DOI] [PubMed] [Google Scholar]

[bibr13-03946320221090330] 13.Muralidharan S, Mandrekar P. (2013) Cellular stress response and innate immune signaling: integrating pathways in host defense and inflammation. Journal of Leukocyte Biology 94(6): 1167–1184. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr14-03946320221090330] 14.Kent SC, Chen Y, Clemmings SM, et al. (2005) Loss of IL-4 Secretion from Human Type 1a Diabetic Pancreatic Draining Lymph Node NKT Cells. Journal of immunology 175(7): 4458–4464. [DOI] [PubMed] [Google Scholar]

[bibr15-03946320221090330] 15.Iyer SS, Cheng G. (2012) Role of interleukin 10 transcriptional regulation in inflammation and autoimmune disease. Critical Reviews in Immunology 32(1): 23–63. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr16-03946320221090330] 16.Cameron MJ, Arreaza GA, Zucker P, et al. (1997) IL-4 prevents insulitis and insulin-dependent diabetes mellitus in nonobese diabetic mice by potentiation of regulatory T helper-2 cell function. Journal of immunology 159(10): 4686–4692. [PubMed] [Google Scholar]

[bibr17-03946320221090330] 17.Reimsnider SK, Eckenrode SE, Marron MP, Muir A, She JX. (2000) IL4 and IL4Rα genes are not linked or associated with type 1 diabetes. Pediatric Research 47(2): 246–249. [DOI] [PubMed] [Google Scholar]

[bibr18-03946320221090330] 18.Allam G, Nasr A, Talaat IM, et al. (2018) Association between cytokine genes polymorphisms and type 1 diabetes: a case-control study on Saudi population. Immunological Investigations 7(3): 229–240. [DOI] [PubMed] [Google Scholar]

[bibr19-03946320221090330] 19.Hollegaard MV, Bidwell JL. (2006) Cytokine Gene Polymorphism in Human Disease: On-Line Databases, Supplement 3. Genes and Immunity. [DOI] [PubMed] [Google Scholar]

[bibr20-03946320221090330] 20.Javor J, Ferencik S, Bucova M, et al. (2010) Polymorphisms in the genes encoding TGF-β1, TNF-α, and IL-6 show association with type 1 diabetes mellitus in the Slovak population. Archivum Immunologiae Et Therapiae Experimentalis (Warsz) 58(5): 385–393. [DOI] [PubMed] [Google Scholar]

[bibr21-03946320221090330] 21.Osman AE, Brema I, AlQurashi A, Al-Jurayyan A, Bradley B, Hamza MA. (2021) Association of single-nucleotide polymorphisms in tumour necrosis factor and human leukocyte antigens genes with type 1 diabetes. International Journal of Immunogenetics 48(4): 326–335. [DOI] [PubMed] [Google Scholar]

[bibr22-03946320221090330] 22.Ding Q, Shi Y, Fan B, et al. (2013) The Interleukin-10 Promoter Polymorphism rs1800872 (-592C>A), Contributes to Cancer Susceptibility: Meta-Analysis of 16 785 Cases and 19 713 Controls. PLoS One 8(2): e57246. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr23-03946320221090330] 23.American Diabetes Association; . 2. Classification and diagnosis of diabetes: Standards of medical care in diabetes-2021. Diabetes Care, 44. 2021;S15. [DOI] [PubMed] [Google Scholar]

[bibr24-03946320221090330] 24.Rodriguez S, Gaunt TR, Day INM. (2009) Hardy-Weinberg equilibrium testing of biological ascertainment for Mendelian randomization studies. American Journal of Epidemiology 169(4): 505–514. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr25-03946320221090330] 25.New Oxford American Dictionary (2013) Choice Rev Online. [Google Scholar]

[bibr26-03946320221090330] 26.Banerjee AK, Guo W, Huang Y. (2019) Genetic and Epigenetic Regulation of Phenotypic Variation in Invasive Plants - Linking Research Trends towards a Unified Framework. NeoBiota. [Google Scholar]

[bibr27-03946320221090330] 27.Li MX, Yeung JMY, Cherny SS, Sham PC. (2012) Evaluating the effective numbers of independent tests and significant p-value thresholds in commercial genotyping arrays and public imputation reference datasets. Human Genetics 131(5): 747–756. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr28-03946320221090330] 28.Brown JJ, Ollier WER, Thomson W, et al. (2006) TNF-α SNP Haplotype Frequencies in Equidae. Tissue Antigens. [DOI] [PubMed] [Google Scholar]

[bibr29-03946320221090330] 29.Osman AE, Eltayeb-ELSheikh N, Mubasher M, et al. (2016) Investigation of activating and inhibitory killer cell immunoglobulin-like receptors and their putative ligands in type 1 diabetes (T1D). Human Immunology 77(1): 110–114. [DOI] [PubMed] [Google Scholar]

[bibr30-03946320221090330] 30.Mehers KL, Long AE, Van Der Slik AR, et al. (2011) An Increased Frequency of NK Cell Receptor and HLA-C Group 1 Combinations in Early-Onset Type 1 Diabetes. Diabetologia. [DOI] [PubMed] [Google Scholar]

[bibr31-03946320221090330] 31.Van der Slik AR, Koeleman BPC, Verduijn W, Bruining GJ, Roep BO, Giphart MJ. (2003) KIR in type 1 diabetes: Disparate distribution of activating and inhibitory natural killer cell receptors in patients versus HLA-matched control subjects. Diabetes 52(10): 2639–2642. [DOI] [PubMed] [Google Scholar]

[bibr32-03946320221090330] 32.Al-Fifi SH. (2010) The relation of age to the severity of Type I diabetes in children. Journal of family & community medicine 17(2): 87–90. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr33-03946320221090330] 33.Shoda LKM, Young DL, Ramanujan S, et al. (2005) A comprehensive review of interventions in the NOD mouse and implications for translation. Immunity 23(2): 115–126. [DOI] [PubMed] [Google Scholar]

[bibr34-03946320221090330] 34.Vaseghi H, Jadali Z. (2016) Th1/Th2 Cytokines in Type 1 Diabetes: Relation to Duration of Disease and Gender. Indian J Endocrinol Metab. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr35-03946320221090330] 35.Inshaw JRJ, Cutler AJ, Crouch DJM, Wicker LS, Todd JA. (2020) Genetic variants predisposing most strongly to type 1 diabetes diagnosed under age 7 years lie near candidate genes that function in the immune system and in pancreatic B-cells. Diabetes Care 43(1): 169–177. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr36-03946320221090330] 36.Redondo MJ, Concannon P. (2020) Genetics of type 1 diabetes comes of age. Diabetes Care 43(1): 16–18. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr37-03946320221090330] 37.Elsid Osman A, Brema I, AlQurashi A, Al-Jurayyan A, Benjamin Bradley MAH. (2021) Association of single-nucleotide polymorphisms in tumour necrosis factor and human leukocyte antigens genes with type 1 diabetes. International Journal of Immunogenetics 48(4): 326–335. [DOI] [PubMed] [Google Scholar]

PERMALINK

Single nucleotide polymorphism rs 2070874 at Interleukin-4 is associated with increased risk of type 1 diabetes mellitus independently of human leukocyte antigens

Awad E Osman

Imad Brema

Alaa AlQurashi

Abdullah Al-Jurayyan

Benjamin Bradley

Muaawia A Hamza

Abstract

Introduction

Objectives

Methods

Results

Conclusion

Introduction

Materials and methods

Table 1.

Statistical analysis

Results

Table 2.

Single nucleotide polymorphisms

Table 3.

HLA-DRB1

Table 4.

HLA-DQA1

Table 5.

HLA-DQB1

Table 6.

HLA-DRB1:DQA1: DQB1 haplotypes

Table 7.

Stratification by SNP and HLA-DRB1 genotype

Table 8.

Table 9.

Stratification by SNP and HLA-DRB: DQA1:DQB1 haplotype

Table 10.

Table 11.

Discussion

Conclusions

Acknowledgements

Footnotes

ORCID iD

References

ACTIONS

PERMALINK

RESOURCES

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