Literature DB >> 30970177

Variants in the BACH2 and CLEC16A gene might be associated with susceptibility to insulin-triggered type 1 diabetes.

Hiroshi Onuma^1,2, Ryoichi Kawamura¹, Yasuharu Tabara³, Masakatsu Yamashita⁴, Jun Ohashi⁵, Eiji Kawasaki⁶, Akihisa Imagawa⁷, Yuya Yamada⁸, Daisuke Chujo⁹, Kenji Takahashi¹⁰, Tadashi Suehiro¹¹, Yasunori Takata¹, Haruhiko Osawa¹, Hideichi Makino^1,12.

Abstract

AIM/
INTRODUCTION: Insulin administration was found to trigger type 1 diabetes in six Japanese type 2 diabetes patients with type 1 diabetes high-risk human leukocyte antigen class II and the class I allele of the insulin gene variable number tandem repeat genotype. The objective of the present study was to assess the contribution of non-human leukocyte antigen single-nucleotide polymorphisms (SNPs) to the risk of developing insulin-triggered type 1 diabetes.
MATERIALS AND METHODS: We genotyped 13 type 1 diabetes susceptible SNPs in six patients and compared them with those in Japanese controls (Hap Map3-JPT). The SNPs that showed statistically significant results were further analyzed using non-diabetic control participants and participants with type 2 diabetes at the Ehime University Hospital.
RESULTS: The risk allele frequency of BACH2 rs3757247 in the six patients was significantly more frequent than that in 86 Japanese controls (P = 0.038). No significant difference in the allele frequency was observed in the other SNPs. This result was confirmed by the findings that the risk allele frequency of BACH2 in the six patients was significantly higher than that in the non-diabetic control participants (n = 179) and type 2 diabetes with or without insulin treatment (n = 154 or n = 152; P = 0.035, 0.034 or 0.037, respectively). Despite being statistically not significant, the six patients were all homozygous for the CLEC16A rs12708716 risk allele and five were homozygous for the CLEC16A rs2903692 risk allele.
CONCLUSIONS: In addition to type 1 diabetes high-risk human leukocyte antigen class II and the class I allele of the insulin gene variable number tandem repeat genotype, the possibility that the risk variants of BACH2 and CLEC16A could contribute to the development of insulin-triggered type 1 diabetes cannot be excluded.

Entities: Chemical

Keywords: zzm321990BACH2zzm321990; zzm321990CLEC16Azzm321990; Insulin-triggered type 1 diabetes

Mesh：

Substances：

Year: 2019 PMID： 30970177 PMCID： PMC6825945 DOI： 10.1111/jdi.13057

Source DB: PubMed Journal: J Diabetes Investig ISSN： 2040-1116 Impact factor: 4.232

Introduction

Type 1 diabetes is an autoimmune disease characterized by an insulin deficiency resulting from the destruction of pancreatic β‐cells1. CD4+ and CD8+ T cells play an important role in the pathogenesis of the disease. Among the autoantigens, insulin plays the most important role in the type 1 diabetes process. In fact, insulin autoantibodies can be detected in children at an early age2, 3. Nakayama et al.4 and Kent et al.5 proposed that insulin itself is the primary autoantigen for autoimmune type 1 diabetes in mice and humans, suggesting that insulin is an essential autoantigen in type 1 diabetes in humans as well as mice. Based on these findings, an intervention trial using oral insulin for human type 1 diabetes was carried out. Recently, TrialNet subsequent to DPT‐1 failed to meet the primary end‐point of delaying or preventing diabetes onset6. Contrary to the intervention trial, it has been reported that the immunization of insulin can induce insulitis, a hallmark of autoimmune type 1 diabetes7, 8. In addition, we previously reported that insulin administration might trigger type 1 diabetes in Japanese type 2 diabetes patients with type 1 diabetes high‐risk human leukocyte antigen (HLA) class II (IDDM1) and the class I allele of the insulin gene variable number tandem repeat genotype (IDDM2)9, 10. The class I allele affects the expression of the insulin gene and the selection of insulin‐specific autoreactive T cells in the thymus11. We suspect that central tolerance might be less efficient due to IDDM1 and IDDM2, resulting in an increase in susceptibility to the T‐cell‐mediated immune response to insulin. In addition, it is also possible that peripheral tolerance might be involved in the pathogenesis of insulin‐triggered type 1 diabetes. Environmental, as well as genetic, factors can contribute to the pathogenesis of type 1 diabetes. The incidence rates for type 1 diabetes varies among ethnic groups, and in contrast to Caucasians, Japanese individuals have one of the lowest levels of incidence, which might be due to the difference in IDDM112, 13. In contrast, as has been reported previously10, IDDM2 is more frequent in the Japanese population14 than in Caucasians15. Genome‐wide association studies using large case–control cohorts of European ancestry revealed the existence of >60 susceptibility loci for type 1 diabetes16. However, their individual contribution to type 1 diabetes risk is low and their function constitutes an issue that remains to be solved. Interestingly, type 1 diabetes risk loci show concordant overlap with other seropositive autoimmune diseases, whereas discordant association is more common in seronegative autoimmune diseases16. Furthermore, >90% of disease‐associated single nucleotide polymorphisms (SNPs) map within the non‐coding regions of the genome, suggesting a regulatory role16. As most variants contribute to only modest effects to disease risk, several studies have evaluated a combination of variants. In The Environmental Determinants of Diabetes in the Young study, eight SNPs were reported to be significantly associated with the development of islet autoimmunity17. The type 1 diabetes TrialNet Study Group recently reported that five SNPs are associated with an increased risk of progression from islet autoantibody positivity to diabetes18. However, it has been difficult to carry out genome‐wide association studies in Japanese individuals with type 1 diabetes because of its low incidence rate. Ikegami et al.19 assembled a multicenter study group in order to carry out large‐scale studies of Japanese individuals, and confirmed several type 1 diabetes susceptible loci that were also reported in Caucasians. Ayabe et al.20 genotyped 63 susceptibility variants in >400 Japanese childhood‐onset autoimmune type 1 diabetes patients, and found 10 risk alleles that were significantly more frequent in type 1 diabetes patients than in non‐diabetic individuals. In the present study, we analyzed 13 type 1 diabetes susceptible SNPs, and compared them with those in controls and patients with type 2 diabetes clarify the genetic background of insulin‐triggered type 1 diabetes patients.

Methods

Participants

Six patients with insulin‐triggered type 1 diabetes were the patients that were reported in our previous study10. Non‐diabetic control participants and participants with type 2 diabetes were recruited from the Ehime University Hospital in Japan. Diabetes mellitus was diagnosed according to the 1998 American Diabetes Association criteria. Non‐diabetic control participants were selected based on the absence of a personal and familial history of diabetes in their first‐degree relatives, as well as either normal glucose tolerance based on a 75‐g oral glucose tolerance test or glycated hemoglobin levels <5.6% with fasting plasma glucose levels <110 mg/dL. All patients and non‐diabetic participants were informed of the purpose of the study, and written consent was obtained from each participant. The study was approved by the ethics committee of the Ehime University Hospital Graduate School of Medicine, and was carried out in accordance with the Declaration of Helsinki.

Genotyping

Genomic DNA was extracted from peripheral blood. A total of 13 type 1 diabetes susceptible SNPs were selected from the genes, which are thought to be immune‐ or pancreatic islet‐related21. The PTPN22 rs2488457, IL2RA rs706778, IL2RA rs3118470, ERBB3 rs2292239, PTPN2 rs1893217, CLEC16A rs12708716, CLEC16A rs2903692, CTLA4 rs3087243, IFIH1 rs1990760, CD226 rs763361, UBASH3A rs9976767, BACH2 rs3757247 and BACH2 rs11755527 were analyzed by a TaqMan probe assay (Applied Biosystems Co., Ltd., Foster City, CA, USA) using commercially available primers and probes purchased from the Assay‐on‐Demand system. An ABI PRISM 7900HT sequence detector (Applied Biosystems) was used to measure the fluorescence levels of the polymerase chain reaction products. The HLA class I and II genotypes were determined as reported previously9.

Statistical analysis

The differences in risk allele frequency of type 1 diabetes susceptibility genes between Japanese controls and the six patients with insulin‐triggered type 1 diabetes was determined by Fisher's exact probability test using HapMap3‐JPT (http://grch37.ensembl.org/Homo_sapiens/Info/Index) data as control Japanese with the js‐STAR version 8.0.1j (Nappa, Tokyo, Japan). The differences in risk allele frequency between non‐diabetic control participants or participants with type 2 diabetes at the Ehime University hospital and the six patients (insulin‐triggered type 1 diabetes) were determined by Fisher's exact probability test.

Results

T allele of BACH2 rs3757247 in the six insulin‐triggered type 1 diabetes was more frequent than that in control Japanese participants (HapMap3‐JPT)

In a previous study, we reported on an analysis of the characteristics of the six patients with insulin‐triggered type 1 diabetes 10. The six patients were composed of four men and two women. The mean age at onset of type 1 diabetes was 59.5 ± 12.8 years. The mean duration of type 2 diabetes until the development of type 1 diabetes was 16.8 ± 11.8 years. The mean body mass index was 24.6 ± 5.0 kg/m2. Insulin treatment was initiated because of deteriorated glycemic control (glycated hemoglobin 9–11%) in all patients. The mean duration of insulin administration until the onset of type 1 diabetes was 7.7 ± 6.1 months. We first genotyped 13 previously reported SNPs associated with type 1 diabetes described in the Methods section in the six patients with insulin‐triggered type 1 diabetes and compared them with those in 86 control Japanese participants using HapMap3‐JPT data (http://grch37.ensembl.org/Homo_sapiens/Info/Index). The results for the genotyping of each SNP in the six patients with insulin‐triggered type 1 diabetes are shown in Table 1. The risk allele (T‐allele) frequency of BACH2 rs3757247 in the six patients with insulin‐triggered type 1 diabetes was 0.75, and was significantly more frequent than that in 86 control Japanese participants (0.43; P = 0.0382). Aside from BACH2 rs3757247, no significant difference in the allele frequency was observed in the other SNPs.

Table 1

Genotype of 13 single‐nucleotide polymorphisms of the type 1 diabetes susceptibility gene in the six patients with insulin‐triggered type 1 diabetes

Nearby gene	SNP	Risk allele	Non‐risk allele	Risk allele frequency (Hap Map3‐JPT)	Case 1	Case 2	Case 3	Case 4	Case 5	Case 6	P
PTPN22	rs2488457	C	G	0.57	G/G	G/G	G/G	G/C	C/C	G/C	0.563
IL2RA	rs706778	T	C	0.48	T/T	T/C	T/C	T/C	C/C	T/C	1
IL2RA	rs3118470	C	T	0.44	C/C	T/C	T/C	T/C	T/T	T/C	0.769
ERBB3	rs2292239	A	C	0.24	C/C	A/C	A/A	C/C	C/C	C/C	1
PTPN2	rs1893217	G	A	0.1	A/A	A/A	A/A	A/A	G/A	A/A	1
CLEC16A	rs12708716	A	G	0.83	A/A	A/A	A/A	A/A	A/A	A/A	0.220
CLEC16A	rs2903692	G	A	0.83	G/G	G/G	G/A	G/G	G/G	G/G	0.694
CTLA4	rs3087243	G	A	0.73	G/A	G/A	G/A	G/G	G/A	G/G	0.740
IFIH1	rs1990760	T	C	0.25	C/C	T/C	C/C	C/C	T/C	T/C	1
CD226	rs763361	T	C	0.47	T/C	T/C	C/C	C/C	C/C	T/T	0.551
UBASH3A	rs9976767	G	A	0.38	G/A	A/A	A/A	G/A	A/A	A/A	0.215
BACH2	rs3757247	T	C	0.43	T/T	T/C	T/T	T/C	T/C	T/T	0.038
BACH2	rs11755527	G	C	0.378	G/G	G/C	G/G	G/C	G/C	G/C	0.066

P refers to the difference of risk allele frequency between control Japanese participants (n = 172) and the six patients (insulin‐triggered type 1 diabetes) were determined using HapMap3‐JPT data (n = 86) by Fisher's exact probability test (two‐sided test). SNP, single‐nucleotide polymorphism.

Genotype of 13 single‐nucleotide polymorphisms of the type 1 diabetes susceptibility gene in the six patients with insulin‐triggered type 1 diabetes P refers to the difference of risk allele frequency between control Japanese participants (n = 172) and the six patients (insulin‐triggered type 1 diabetes) were determined using HapMap3‐JPT data (n = 86) by Fisher's exact probability test (two‐sided test). SNP, single‐nucleotide polymorphism.

T allele of BACH2 rs3757247 in insulin‐triggered type 1 diabetes was more frequent than that in non‐diabetic control participants and participants with type 2 diabetes

We further genotyped the BACH2 rs3757247, the risk allele frequency of which is significantly different in risk allele frequency between the six patients with insulin‐triggered type 1 diabetes and 86 control Japanese participants using HapMap3‐JPT data in non‐diabetic control participants (n = 179), type 2 diabetes patients with insulin treatment (n = 154), and type 2 diabetes patients without insulin treatment (n = 152) at the Ehime University Hospital (Table 2). The frequency of the T allele in non‐diabetic control participants, type 2 diabetes patients with insulin treatment and type 2 diabetes patients without insulin treatment was found to be 0.42, 0.42 and 0.43, respectively. The T allele frequency of BACH2 in the six patients with insulin‐triggered type 1 diabetes (0.75) was found to be significantly higher than that in non‐diabetic control participants and type 2 diabetes patients with and without insulin treatment (P = 0.035, 0.034 and 0.037, respectively). As for the genotype frequency, there was a trend in the same direction, but did not reach statistical significance.

Table 2

BACH2 rs3757247	n	Genotype			P	Allele		P
BACH2 rs3757247	n	T/T	C/T	C/C	P	T	C	P
Insulin‐triggered T1D	6	3	3	0	*	9 (75%)	3 (25%)	*
Non‐diabetic control	179	33	85	61	0.0665	151 (42.2%)	207 (57.8%)	0.0352
T2D with insulin therapy	154	27	74	53	0.063	128 (41.5%)	180 (58.5%)	0.0338
T2D without insulin therapy	152	31	68	53	0.0766	130 (42.7%)	174 (57.3%)	0.0367

P: the difference of genotype and risk allele frequency between the six patients (insulin‐triggered type 1 diabetes) and non‐diabetic control participants and patients with type 2 diabetes were determined by Fisher's exact probability test (two‐sided test). *, reference; T1D, type 1 diabetes; T2D, type 2 diabetes.

Genotypes and allele frequency of BACH2 rs3757247 in the six patients with insulin‐triggered type 1 diabetes compared with non‐diabetic controls and type 2 diabetes patients with or without insulin therapy P: the difference of genotype and risk allele frequency between the six patients (insulin‐triggered type 1 diabetes) and non‐diabetic control participants and patients with type 2 diabetes were determined by Fisher's exact probability test (two‐sided test). *, reference; T1D, type 1 diabetes; T2D, type 2 diabetes.

Total risk allele count in each SNP in the six patients with insulin‐triggered type 1 diabetes

The total risk allele count in each SNP for the six patients with insulin‐triggered type 1 diabetes is shown in Figure 1. The black bar indicates the risk variant having one or two risk alleles in each patient with insulin‐triggered type 1 diabetes. The six patients with insulin‐triggered type 1 diabetes were all homozygous for the risk allele of CLEC16A rs12708716, and five patients were homozygous for the risk allele of CLEC16A rs2903692. The risk allele count for BACH2 rs3757247 was nine, and that of BACH2 rs11755527and CTLA4 rs3087243 were both eight, respectively.

Figure 1

Total risk allele count in each single‐nucleotide polymorphism (SNP) of the six patients. The number of total risk alleles in each type 1 diabetes susceptible SNP of the six patients were counted. The black bars show the SNP having one or two risk alleles in each patient with insulin‐triggered type 1 diabetes.

HLA class II and class I genotypes in the six patients with insulin‐triggered type 1 diabetes

As reported previously10, all of the patients had type 1 diabetes susceptible HLA class II haplotypes, as reported for Japanese, such as DRB1*04:05‐DQB1*04:01 and/or DRB1*09:01‐DQB1*03:03 (Table 3). Three patients had type 1 diabetes susceptible DPB1*02:01 allele, as reported in Japanese patients with type 1 diabetes12, 22. Regarding the HLA class I alleles, five patients (patients 1, 3, 4, 5 and 6) had type 1 diabetes susceptible alleles – A*24:02, B*40:06 or B*54:01 and Cw*01:02 or Cw*08:01 – as has been previously reported in Japanese patients with type 1 diabetes 12, 22. Patient 2 had none of these type 1 diabetes susceptible alleles, but his clinical characteristics were similar to those of the other five patients.

Table 3

Human leukocyte antigen‐class II and I genotypes in the six patients with insulin‐triggered type 1 diabetes

HLA	Patient 1	Patient 2	Patient 3	Patient 4	Patient 5	Patient 6
DRB1	04:05/09:05	08:03/09:01	04:05/04:05	01:01/09:01	04:05/14:07	09:01/09:01
DQB1	03:03/04:01	03:01/03:03	04:01/04:01	03:03/05:01	04:01/05:02	03:03/03:03
DPB1	05:01/05:01	05:01/14:01	02:01/09:01	02:01/02:01	05:01/14:01	02:01/05:01
A	02:01/02:01	02:01/02:01	11:01/24:02	24:02/26:02	24:02/31:01	24:02/26:02
B	40:01/54:01	38:02/40:01	15:01/54:01	40:06/52:01	48:01/54:01	40:06/51:01
C	Cw01:02/03:04	Cw03:04/07:02	Cw01:02/04:01	Cw08:01/12:02	Cw01:02/08:03	Cw08:01/14:02

HLA, human leukocyte antigen.

Human leukocyte antigen‐class II and I genotypes in the six patients with insulin‐triggered type 1 diabetes HLA, human leukocyte antigen.

Discussion

The findings reported herein show that BACH2 rs3757247 was significantly more frequent in the six patients with insulin‐triggered type 1 diabetes than in non‐diabetic control participants and type 2 diabetes patients with or without insulin treatment. BACH2 is a transcription factor associated with a super‐enhancer, and the gene is located on human chromosome 6q1523. The SNPs, rs375724724 and rs1175552725, which are in tight linkage disequilibrium (LD), have been reported to be associated with type 1 diabetes in Caucasian individuals. Ayabe et al.20 confirmed the association of rs3757247 in Japanese individuals with childhood‐onset type 1 diabetes. Several SNPs in LD in the BACH2 locus are associated with a variety of autoimmune diseases23, suggesting that its function might be related to fundamental immune regulation. In fact, using Bach2 knockout mice, Roychoudhuri et al.26 showed a fatal inflammation, especially in the lung and colon, with anti‐nuclear autoantibodies when the mice were several months old. They suggested that Bach2 is a key regulator of the generation of regulatory T cells (Tregs) and effector T‐cell differentiation, processes that prevent the development of inflammatory diseases by controlling the balance between tolerance and immunity. Afzali et al.27 reported on a heterozygous point mutation in the BACH2 locus in the two families who showed autoimmune gastrointestinal disease, recurrent respiratory tract infections and an immunoglobulin deficiency. They also proposed that BACH2 is a key regulator of the human adaptive immune system, which is critical to the maintenance of Tregs formation and B‐cell maturation. Furthermore, they also proposed that in super‐enhancer‐associated genes, such as the BACH2 gene, small changes in expression level might lead to amplified changes in their associated network, resulting in significant pathological changes. In a previous study, we observed typical insulitis in the islets of one patient, and insulin‐peptides‐reactive type 1 T helper cells, as well as an insulin allergy or a high titer of insulin antibody in several other patients9, 10. Although rs3757247 is an intronic variant that is located in the intron 2 of the BACH2 locus, it is possible that slight changes in the expression level might lead to significant alterations in Tregs function, resulting in a T‐cell‐mediated immune response to insulin. Indeed, the histone H3K27 hyperacetylation region and DNase I hypersensitive sites have been reported in the proximity region of the rs3757247 and rs11755527 (UCSC Genome Browser on Human Assembly: GRCh38/hg38; Figure 2). It is well established that the active enhancers can be identified by enrichment of both H3K27 and hypersensitive sites for DNase I28, 29. Both SNPs might be located in the enhancer region of the BACH2 gene and could, therefore, have an influence on BACH2 transcription in Tregs.

Figure 2

Both single‐nucleotide polymorphisms (SNPs), rs3757247 and rs11755527, might be located in the enhancer region of the BACH2 gene (UCSC Genome Browser on Human Assembly: GRCh38/hg38). DNase clusters: DNase I Hypersensitivity Clusters from ENCODE (95 cell types) are shown as the grey boxes. H3K27ac: H3K27AC MARK (Often Found Near Regulatory Elements) on T‐cell lines from ENCODE are shown as the pink waveform. As shown in Figure 1, all six of the patients were homozygous for the risk allele of CLEC16A rs12708716, and five patients were homozygous for the risk allele of CLEC16A rs2903692, suggesting a causal relationship with the present patients, despite the fact that the data were not statistically significant. CLEC16A is an atypical C‐type lectin, and the gene is located on human chromosome 16p1330. SNPs, rs2903692 (intron 22) and rs12708716 (intron 19), which are in tight LD have been reported to be associated with Caucasian subjects with type 1 diabetes 31, 32, 33. Awata et al.34 confirmed the association of rs2903692 in Japanese subjects with type 1 diabetes. Several SNPs in LD in the CLEC16A locus (formerly referred to as KIAA0350) are associated with other autoimmune diseases35. Therefore, its function might be related to fundamental immune regulation, as has been suggested for the BACH2 gene. Schuster et al.35 reported that Clec16A knockdown mice showed a diminished diabetogenicity of non‐obese diabetic T cells, which might be due to an alteration in the thymic epithelial cell (TEC) stimulation of thymocytes owing to impaired autophagy. As the complete absence of Atg5, which is an essential component of autophagosome formation, was found to be lethal in neonate mice, Nedjic et al.36 transplanted embryonic Atg5‐deficient thymi under the capsule of a normal adult recipient. They found that the selection of certain major histocompatibility complex‐restricted T‐cell specificities and severe inflammation in the colon and liver had been altered, and concluded that autophagy in TEC contributes to T‐cell selection and is essential for the generation of a self‐tolerant T‐cell repertoire. Although CLEC16A in TEC might not have as strong an effect on its autophagy as that of ATG5, it is possible that the intronic variants of CLEC16A might cause slight changes in the autophagy of TEC, resulting in a less efficient deletion of insulin‐specific autoreactive T cells. Until now, insulin‐triggered type 1 diabetes has been reported only in Japanese individuals, but not from other countries. In a previous study, we reported a significantly higher odds ratio of IDDM2 in Japanese patients with type 1 diabetes than in Caucasian patients with type 1 diabetes 10. Ayabe et al.20 recently reported a high odds ratio for IDDM2 using SNP rs689 in Japanese patients with type 1 diabetes, which prompted us to again compare the odds ratio for the rs689 genotype between Japanese and Caucasian patients with type 1 diabetes37, and the results are shown in Table 4. We confirmed a significantly higher odds ratio of the IDDM2 genotype in Japanese patients with type 1 diabetes compared with those of Caucasian patients with type 1 diabetes (P = 0.042), indicating that Japanese individuals might be more sensitive to insulin autoimmunity than Caucasians. In fact, insulin‐triggered type 1 diabetes, as well as insulin autoimmune syndrome, has been reported exclusively in Japanese individuals10.

Table 4

Odds ratios for the association between INS rs689 and type 1 diabetes in Japanese and Caucasian individuals

	Genotype	Type 1 diabetes	Non‐diabetic control	OR (95% CI)
Japanese (Ayabe et al.20)		(n = 852)	(n = 910)
	I/I	847(99.4%)	881 (96.8%)	5.58 (2.15–14.47)
	I/III or III/III	5 (0.6%)	29 (3.2%)
Caucasian (Bjørnvold et al.37)		(n = 1,251)	(n = 1,413)
	I/I	903 (72.2)	779 (55.1%)	2.11(1.80–2.48)
	I/III or III/III	348 (27.8%)	634 (44.9%)

In Ayabe's study, the T allele in INS689 was reported as a risk allele (I), which corresponded to major alleles in Japanese individuals. CI, confidence interval; OR, odds ratio.

Odds ratios for the association between INS rs689 and type 1 diabetes in Japanese and Caucasian individuals In Ayabe's study, the T allele in INS689 was reported as a risk allele (I), which corresponded to major alleles in Japanese individuals. CI, confidence interval; OR, odds ratio. In conclusion, the risk variants of CLEC16A, as well as IDDM1 and IDDM2, could result in a less efficient deletion of insulin‐specific autoreactive T cells in the thymus. As the variant of BACH2 could have a slightly altered Tregs function, it could not make an adjustment for the derangement of insulin‐specific autoreactive T cells in the periphery, resulting in the development of insulin‐triggered type 1 diabetes. However, as direct evidence for the function of these variants was lacking in the present study, further work will be required to clarify the pathological mechanism responsible for the present patients. Furthermore, as the present study only included a very small sample size, it will be necessary to confirm the findings in follow‐up studies with additional insulin‐triggered type 1 diabetes patients.

Disclosure

The authors declare no conflict of interest.

37 in total

Review 1. Structure and function of active chromatin and DNase I hypersensitive sites.

Authors: Peter N Cockerill
Journal: FEBS J Date: 2011-05-26 Impact factor: 5.542

Review 2. T Cell Fates Zipped Up: How the Bach2 Basic Leucine Zipper Transcriptional Repressor Directs T Cell Differentiation and Function.

Authors: Martin J Richer; Mark L Lang; Noah S Butler
Journal: J Immunol Date: 2016-08-15 Impact factor: 5.422

3. Autoantibody appearance and risk for development of childhood diabetes in offspring of parents with type 1 diabetes: the 2-year analysis of the German BABYDIAB Study.

Authors: A G Ziegler; M Hummel; M Schenker; E Bonifacio
Journal: Diabetes Date: 1999-03 Impact factor: 9.461

Review 4. Genetics of type 1 diabetes: what's next?

Authors: Flemming Pociot; Beena Akolkar; Patrick Concannon; Henry A Erlich; Cécile Julier; Grant Morahan; Concepcion R Nierras; John A Todd; Stephen S Rich; Jørn Nerup
Journal: Diabetes Date: 2010-07 Impact factor: 9.461

5. Differential association of HLA with three subtypes of type 1 diabetes: fulminant, slowly progressive and acute-onset.

Authors: Y Kawabata; H Ikegami; T Awata; A Imagawa; T Maruyama; E Kawasaki; S Tanaka; A Shimada; H Osawa; T Kobayashi; T Hanafusa; K Tokunaga; H Makino
Journal: Diabetologia Date: 2009-10-08 Impact factor: 10.122

6. Insulin administration may trigger type 1 diabetes in Japanese type 2 diabetes patients with type 1 diabetes high-risk HLA class II and the insulin gene VNTR genotype.

Authors: Wataru Nishida; Masao Nagata; Akihisa Imagawa; Toshiaki Hanafusa; Jun Ohashi; Kenji Takahashi; Tadashi Suehiro; Yuya Yamada; Daisuke Chujo; Eiji Kawasaki; Ryoichi Kawamura; Hiroshi Onuma; Haruhiko Osawa; Hideichi Makino
Journal: J Clin Endocrinol Metab Date: 2014-06-27 Impact factor: 5.958

Review 7. Genetics and pathogenesis of type 1 diabetes: prospects for prevention and intervention.

Authors: Hiroshi Ikegami; Shinsuke Noso; Naru Babaya; Yumiko Kawabata
Journal: J Diabetes Investig Date: 2011-11-30 Impact factor: 4.232

8. Follow-up analysis of genome-wide association data identifies novel loci for type 1 diabetes.

Authors: Struan F A Grant; Hui-Qi Qu; Jonathan P Bradfield; Luc Marchand; Cecilia E Kim; Joseph T Glessner; Rosemarie Grabs; Shayne P Taback; Edward C Frackelton; Andrew W Eckert; Kiran Annaiah; Margaret L Lawson; F George Otieno; Erin Santa; Julie L Shaner; Ryan M Smith; Robert Skraban; Marcin Imielinski; Rosetta M Chiavacci; Robert W Grundmeier; Charles A Stanley; Susan E Kirsch; Daryl Waggott; Andrew D Paterson; Dimitri S Monos; Constantin Polychronakos; Hakon Hakonarson
Journal: Diabetes Date: 2008-10-07 Impact factor: 9.461

9. Joint effects of HLA, INS, PTPN22 and CTLA4 genes on the risk of type 1 diabetes.

Authors: M Bjørnvold; D E Undlien; G Joner; K Dahl-Jørgensen; P R Njølstad; H E Akselsen; K Gervin; K S Rønningen; L C Stene
Journal: Diabetologia Date: 2008-02-22 Impact factor: 10.122

Review 10. Type 1 diabetes genome-wide association studies: not to be lost in translation.

Authors: Flemming Pociot
Journal: Clin Transl Immunology Date: 2017-12-01

5 in total

1. BACH2 inhibition reverses β cell failure in type 2 diabetes models.

Authors: Jinsook Son; Hongxu Ding; Thomas B Farb; Alexander M Efanov; Jiajun Sun; Julie L Gore; Samreen K Syed; Zhigang Lei; Qidi Wang; Domenico Accili; Andrea Califano
Journal: J Clin Invest Date: 2021-12-15 Impact factor: 14.808

2. First-appearing islet autoantibodies for type 1 diabetes in young children: maternal life events during pregnancy and the child's genetic risk.

Authors: Suzanne Bennett Johnson; Kristian F Lynch; Roswith Roth; Markus Lundgren; Hemang M Parikh; Beena Akolkar; William Hagopian; Jeffrey Krischer; Marian Rewers; Jin-Xiong She; Jorma Toppari; Anette G Ziegler; Åke Lernmark
Journal: Diabetologia Date: 2021-01-06 Impact factor: 10.460

Review 3. The Critical Role of Bach2 in Shaping the Balance between CD4⁺ T Cell Subsets in Immune-Mediated Diseases.

Authors: Lingyi Yang; Shuli Chen; Qiuyu Zhao; Ying Sun; Hong Nie
Journal: Mediators Inflamm Date: 2019-12-30 Impact factor: 4.711

Review 4. Advances in Knowledge of Candidate Genes Acting at the Beta-Cell Level in the Pathogenesis of T1DM.

Authors: Haipeng Pang; Shuoming Luo; Gan Huang; Ying Xia; Zhiguo Xie; Zhiguang Zhou
Journal: Front Endocrinol (Lausanne) Date: 2020-03-12 Impact factor: 5.555

5. Recurrent Hypoglycemia Due to a High Titer of Insulin Antibody in Response to Exogenous Insulin Administration in Two Cases of Type 1 Diabetes.

Authors: Ryoichi Kawamura; Satoshi Miyao; Hiroshi Onuma; Yasuko Uchigata; Eiji Kawasaki; Jun Ohashi; Sanshiro Shiraishi; Wataru Nishida; Maki Yokomoto-Umakoshi; Yasunori Takata; Haruhiko Osawa; Hideichi Makino
Journal: Intern Med Date: 2021-08-31 Impact factor: 1.271