Genes predisposing to type 1 diabetes mellitus and pathophysiology: a narrative review
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Med J Indones mji.ui.ac.id
Genes predisposing to type 1 diabetes mellitus and pathophysiology: a narrative review
Tajudeen Yahaya,¹ Titilola Salisu²
Medical
Journal of
Indonesia
Review Article
ABSTRACT
The possibility of targeting the causal genes along with the mechanisms of pathogenically complex diseases has led to numerous studies on the genetic etiology of some diseases. In particular, studies have added more genes to the list of type 1 diabetes mellitus (T1DM) suspect genes, necessitating an update for the interest of all stakeholders. Therefore this review articulates T1DM suspect genes and their pathophysiology. Notable electronic databases, including Medline, Scopus, PubMed, and Google-Scholar were searched for relevant information. The search identified over 73 genes suspected in the pathogenesis of T1DM, with human leukocyte antigen, insulin gene, and cytotoxic T lymphocyte-associated antigen 4 accounting for most of the cases. Mutations in these genes, along with environmental factors, may produce a defective immune response in the pancreas, resulting in β-cell autoimmunity, insulin deficiency, and hyperglycemia. The mechanisms leading to these cellular reactions are gene-specific and, if targeted in diabetic individuals, may lead to improved treatment.
Medical practitioners are advised to formulate treatment procedures that target these genes in patients with T1DM.
KEYWORDS autoimmunity, hyperglycemia, insulin, pancreas, type 1 diabetes mellitus pI SSN: 0853-1773 • eISSN: 2252-8083https://doi.org/10.13181/mji.rev.203732
Med J Indones. 2020;29:100–9Received:
April 24, 2019
Accepted:
January 23, 2020
Authors' affiliations: ¹Department of Biology, Faculty of Science, Federal University Birnin Kebbi, Kebbi State, Nigeria, ²Department of Zoology and Environmental Biology, Olabisi Onabanjo University Ago-Iwoye, Ogun State, Nigeria
Corresponding author:
Tajudeen Yahaya
Department of Biology, Faculty of Science, Federal University Birnin Kebbi, Kebbi State, Nigeria
Tel/Fax: +234-8033550788/ +234-8098233774
E-mail: [email protected]/ [email protected]
Diabetes mellitus (DM) begins when hyperglycemia occurs. A hormone synthesized by the pancreatic β-cells, known as insulin, regulates blood glucose by transporting it from the bloodstream into the cells where it is metabolized. Another hormone produced by the pancreatic α-cells, known as glucagon, also assists the body in the blood glucose regulation process. In most cases, type 1 diabetes mellitus (T1DM) occurs when the immune system, which normally attacks only foreign antigens, faultly destroys the β -cells. Consequently, the pancreas stops making insulin, leading to the retention of glucose in the blood.¹ Some people develop a condition known as secondary DM, which is like T1DM, but the immune system does not destroy the β -cells.² Instead, the cells are removed by certain stimuli in the pancreas, as indicated by histopathological changes.² T1DM was previously named juvenile DM but was renamed because adults can also develop the disease. Moreover, T1DM is not the only form of DM that affects children and young adults. Particularly, type 2 diabetes mellitus (T2DM) is becoming increasingly prevalent among young Copyright @ 2020 Authors. This is an open access article distributed under the terms of the Creative Commons Attribution-NonCommercial 4.0 International License (http://creativecommons.org/licenses/by-nc/4.0/), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original author and source are properly cited. For commercial use of this work, please see our terms at https://mji.ui.ac.id/journal/index.php/mji/copyright. ahaya, et al. | Type 1 diabetes mellitus suspect genes
Medical
Journal of
Indonesia individuals as more and more children are becoming obese and overweight nowadays.³ Maturity-onset diabetes of the young and neonatal diabetes mellitus are other forms of DM that mainly affect children and neonates with different clinical features from T1DM.
T1DM is the most frequent chronic illness among children, accounting for 5–10% of all DM cases.² It is the most burdensome form of DM, with a decreased life expectancy.⁴ About 30 million people live with T1DM worldwide, and the prevalence is predicted to increase three-fold in the 2040s.⁵ Uncontrolled T1DM may cause chronic complications, including retinopathy, nephropathy, neuropathy, and vascular diseases. T1DM has a strong genetic etiology modulated by some environmental triggers that may prevent the disease if avoided before autoimmunity. The treatment involves constant insulin injections, which is expensive; thus, a better approach is necessary to stem the burden of the disease. As autoimmunity is the hallmark of T1DM, an intervention that re-programs the immune system may be a potential way to treat the disease. This observation suggests that precision medicine that targets causal genes and the pathophysiology of complicated diseases, such as DM, may provide a future management when fully understood. Hence, this review was initiated to search notable electronic databases, including Medline, Scopus, PubMed, and Google-Scholar to establish T1DM suspected genes. The result will facilitate the formulation of drugs and treatment procedures that target these genes and their mechanisms.
T1DM SUSPECT GENES
At least 18 regions in the human genome were identified as hotspots for T1DM using genome-wide linkage analysis. These regions host many genes and are labeled
IDDM1-IDDM18 because T1DM was formerly called insulin-dependent DM (IDDM).⁶
However, improvement in biological techniques has led to a greater understanding of the genetic basis of T1DM. More precise studies have reaffirmed the roles of some previously suspected genes in T1DM pathogenesis and new ones have been discovered. Many genes have been reportedly linked with T1DM, but only those with clear mechanisms are presented in this review. Tables 1–3 show the update on T1DM candidate genes, grouped according to their mechanisms of action, which are disruption of T cell regulatory activities, increased susceptibility to microbial infection, oxidative stress, cytokine- induced β-cell loss, and β-cell reconfiguration . However, more genes are being added continually.
Most frequently suspected T1DM predisposing genes
Of the genes described in Tables 1–3, mutations in the major histocompatibility complex (MHC), insulin gene (
INS ), cytotoxic T lymphocyte-associated protein 4 (
CTLA4 ), protein tyrosine phosphatase, non-receptor type 2 (
PTPN2 ), and protein tyrosine phosphatase, non-receptor type 22 (
PTPN22 ) genes account for most of the T1DM cases. Detailed information on the diabetogenic activities of these genes is given below.
Gene
Full name Locus Mechanism
CTLA4
Cytotoxic T-lymphocyte associated protein 4 2q33.2 Causes massive lymphocyte proliferation, resulting in overexpression of T cells, which attack self-antigens, leading to β-cell apoptosis.⁷
FOXP3
Forkhead box P3 Xp11.23 Disrupts the activities of many endocrine glands, affecting the immune regulatory T cells and setting of autoimmunity.⁸
PRKCQ
Protein kinase C theta 10p15.1 Loss of T cell signaling, leading to a compromised immune system.⁹
IL7R
Interleukin 7 receptor 5p13.2 Causes a compromised immune system, characterized by depletion of T cells.¹⁰
IL2
Interleukin 2 4q27 Causes functional loss of T cell (Treg) regulation, resulting in autoimmunity.¹¹
ITGB7
Integrin subunit beta 7 12q13.13 It disrupts the activities of T cells in the pancreas, resulting in autoimmunity.¹²
SH2B3
SH2B adaptor protein 3 12q24.13 Increases self-reactive T lymphocyte proliferation.¹³
RASGRP1
RAS guanyl releasing protein 1 15q14 Reduced expression results in splenomegaly and autoantibodies, while complete deletion decreases T cell development in the thymus.¹⁴
Table 1.
T1DM suspect genes that disrupt T cell immune regulatory activities and increase susceptibility to microbial infection Med J Indones mji.ui.ac.id
Gene
Full name Locus Mechanism
CD28
CD28 molecule 2q33.2 Mediates loss of function of regulatory T cells, leading to autoimmunity of the pancreatic β-cells.¹⁵
ICOS
Inducible T cell costimulator 2q33.2 It suppresses insulin-specific regulatory T cells.¹⁶
ART2/RT6
Antisense to ribosomal RNA transcript protein 2 11p15.4 Causes insulitis in which the islets are massively infiltrated by macrophages and T cells.¹⁷
UBASH3A
Ubiquitin associated and SH3 domain containing A 21q22.3 Increases UBASH3A expression in CD4+ T cells, disrupting NF-κB signaling, which in turn represses
IL2 gene expression.¹⁸
SUMO4
Small ubiquitin-like modifier 4 6q25.1 Reduces sumoylation capacity, causing overexpression of NF-κB and IL12B, and leading to β-cell autoimmunity.¹⁹MHC Major histocompatibility complex 6p21.31 Causes loss of T cell signaling, leading to autoimmunity of the pancreatic β-cells.²⁰
NRP1
Neuropilin 1 10p11.22 Causes defects in Treg phenotype decreasing its signaling activities, culminating in autoimmunity of the β-cells.²¹
MIF
Macrophage migration inhibitory factor 22q11.23 Causes high MIF concentrations in the blood, resulting in dysfunctional pancreatic islets. Also causes loss of function of immune cells, such as macrophages and T cells, increasing the risk of β-cell autoimmunity.²²
CD226
Cluster of differentiation 226 18q22.2 Increases the frequency of GAD autoantibody and lowers C-peptide levels, accelerating β-cell destruction.²³
IL6
Interleukin 6 7p15.3 Impairs immune response, leading to β-cell autoimmunity, it also leads to impaired fat breakdown in tissues such as muscle cells.²⁴
IL10
Interleukin 10 1q32.1 It negatively regulates a T cell called Th17, setting up autoimmunity of the pancreatic β-cells.²⁵
IL12B
Interleukin 12B 5q31-33 It negatively regulates a T cell called Th17, setting up autoimmunity of the pancreatic β-cells.²⁶
PTPN22
Protein tyrosine phosphatase, non-receptor type 22 1p13.2 Disrupts elimination of autoreactive β-cells, and upregulates certain β-cell genes, leading to β-cell death.²⁷
VDR
Vitamin D receptor 12q13.11 It causes dysfunctional immune mechanism, leading to autoimmunity.²⁸
IL26
Interleukin 26 12q15 Disrupts sensing of bacteria by the defense mechanism,²⁹ resulting in the attack of β-cells.
TAGAP
T cell activation RhoGTPase activating protein 6q25.3 Causes deficiency of several important regulators of antiviral response, including IFN-β, culminating in loss of antiviral signaling pathways, and β-cell autoimmunity.³⁰
TYK2
Tyrosine kinase 2 19p13.2 Represses TYK2, predisposing the body to virus attack.³¹
GAD2
Glutamic acid decarboxylase 2 10p12.1 Promotes invasion of β-cells by viruses, setting of autoimmunity of the β-cells, leading to insulin deficiency.³²
OAS1
IFIH1
Interferon induced with helicase C domain 1 2q24.2 Produces abnormal antiviral immune response, increasing the risk of autoimmunity.³⁴
FUT2
Fucosyltransferase 2 19q13.33 Alters the gut microbiome, increasing the risk of autoimmunity of the β-cells.³⁵
Table 1. (continued)
T1DM=type 1 diabetes mellitus; Treg=regulatory T cell; NF- κB=nuclear factor kappa B; Th17=T helper 17 cells; IFN-β=interferon beta ahaya, et al. | Type 1 diabetes mellitus suspect genes
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Gene
Full name Locus Mechanism
SIRT1
Sirtuin 1 10q21.3 Produces defective sirtuin, inducing cytokines to attack wrong cells, particularly β-cells. ERBB3
Erb-B2 receptor tyrosine kinase 3 12q13.2 Disrupts antigen presentation, causing cytokine-induced β-cell apoptosis. PTPN2
Protein tyrosine phosphatase, non-receptor type 2 18p11.21 Produces cytokine, which induces destruction of β-cells and mitochondrial apoptotic pathway, disrupting glucose metabolism. BACH2
BTB domain and CNC homolog 2 6q15 Decreases
PTPN2 expression, promoting pro-inflammatory cytokine-induced β-cell apoptosis. IL21
Interleukin 21 4q27 Causes inflammatory infiltration of pancreatic islets. CENPW/C6orf173
Centromere protein W 6q22.32 Contributes to the generation of autoantibodies in the islets. AFF3
AF4/FMR2 family member 3 2q11.2 Alters the expression of monocytes as well as macrophages and dendritic cells, causing gradual destruction of β-cells. TNFAIP3
Tumor necrosis factor alpha induced protein 3 6q23.3 Loss of functional regulation of β-cell apoptosis, leading to poor glycemic control. RNLS
Renalase, FAD dependent amine oxidase 10q23.31 Alters the expression of monocytes as well as macrophages and dendritic cells, causing gradual destruction of β-cells. GPR183/EBI2
G protein-coupled receptor 183 13q32.3 Changes the expression of monocytes as well as macrophages and dendritic cells, causing gradual destruction of β-cells. CLECL1
C-type lectin like 1 12p13.31 Alters the expression of monocytes as well as macrophages and dendritic cells, causing gradual destruction of β-cells. DEXI
Dexamethasone-induced protein 16p13.13 Depletes gut microbial metabolites, causing autoimmunity of β-cells. SUOX
Sulfite oxidase 12q13.2 Alters the expression of monocytes as well as macrophages and dendritic cells, causing gradual destruction of β-cells. SMARCE1
SWI/SNF related, matrix associated, actin dependent regulator of chromatin, subfamily e, member 1 17q21.2 Alters the expression of monocytes as well as macrophages and dendritic cells, causing gradual destruction of β-cells. FKRP
Fukutin-related protein 19q13.32 Alters the expression of monocytes as well as macrophages and dendritic cells, causing gradual destruction of β-cells. IL27
Interleukin 27 16p11.2 Promotes inflammations of the islet cells. SOD2
Superoxide dismutase 2 6q25.3 Enhances generation of free oxygen radical, stressing, and contributing to β-cell death. BCL-2
B-cell leukemia/lymphoma 2 18q21.33 Initiates intracellular apoptotic pathway, resulting in islet cell death. FAS/CD95
Fas cell surface death receptor 10q23.31 Initiates glucose-induced DNA fragmentation, resulting in pancreatic islet apoptosis. IL-1A
Interleukin 1 alpha 2q14.1 Initiates glucose-induced DNA fragmentation, resulting in pancreatic islet apoptosis. APOC3
Apolipoprotein C3 11q23.3 Causes influx of Ca into the β-cells, destroying the cells. BAD
BCL2-associated agonist of cell death 11q13.1 Loss of control of programmed cell death. NOS2
Nitric oxide synthase 2 17q11.2 Produces nitric oxide, inducing apoptosis in several cells, including β-cells. Table 2.
T1DM suspect genes that mediate oxidative stress and cytokine-induced β -cell loss Med J Indones mji.ui.ac.id
Gene
Full name Locus Mechanism
INS
Insulin gene 11p15.5 Breakage of phenylalanine amino acid, hampering maturation of preproinsulin to insulin. HNFIA
Hepatocyte nuclear factor-1 alpha 12q2431 Disruption of insulin biosynthesis, leading to hyperglycemia and osmotic diuresis. SLC2A2
Solute carrier family 2 member 2 3q26.2 Fanconi-Bickel syndrome, causing lack of insulin in utero. Amylin
Islet amyloid polypeptide 12p12.1 Causes over secretion of amylin, which aggregate in the pancreatic β-cells, causing β-cell death and impairing insulin secretion. NKX2.2
NK2 homeobox 2 20p11.22 Causes β-cell reconfiguration, leading to loss of insulin synthesis. GLIS3
GLI-similar 3 9p24.2 Suppresses insulin gene expression, causing pancreatic β-cell death. NEUROD1
Neuronal differentiation 1 2q32 Affects β-cell morphogenesis and differentiation, promoting β-cell apoptosis. CTSH
Cathepsin H 15q25.1 Progressively reduces the survival of β-cells. DLL1
Delta-like1-Drosophila 6q27 Hampers β-cell differentiation and maturation. ORMDL3 GSDMB
Orosomucoid like 3 17q12 Reduces sulfatide levels in the pancreatic islet, causing unregulated proinsulin folding as well as apoptosis. FADD
Fas-associated death domain 11q13.3 Disrupts transcription of pancreatic cells. CDKN1B/p27KIP1
Cyclin-dependent kinase inhibitor 1B 12p13.1 Causes loss of β-cell mass, and poor glucose metabolism. IRS2
Insulin receptor substrate 2 13q34 Reduces β-cell mass. IL2RA/CD25
Interleukin 2 receptor alpha 10p15.1 Causes inflammatory bowel disease, β-cell enlargement, leading to autoimmunity. Table 3.
T1DM suspect genes that reconfigure β -cell morphology and identity
T1DM=type 1 diabetes mellitus
Gene
Full name Locus Mechanism
PTEN
Phosphatase and tensin homolog 10q23.31 Causes gradual destruction of β-cells. CASP7
Caspase 7 10q25.3 Causes gradual destruction of β-cells. HIP14
Huntingtin-interacting protein 14 Accelerates apoptotic cell death. STAT4
Signal transducer and activator of transcription 4 2q32.2 Its activation causes cytokine-induced islet apoptosis, resulting in β-cell dysfunction. CCR5
C-C chemokine receptor 5 3p21.31 Mediates infiltration of the pancreatic islets by abnormal blood cells, culminating in the gradual destruction of β-cells. ITPR3
Inositol 1,4,5-trisphosphate receptor type 3 6p21.31 Causes dysregulated calcium transport, leading to loss of insulin secretion function of the β-cells, culminating in high blood glucose and high HbA1c beyond healthy levels. T1DM=type 1 diabetes mellitus; HbA1c=hemoglobin A1c
Table 2. (continued) ahaya, et al. | Type 1 diabetes mellitus suspect genes
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MHC
MHC is about a 4 megabases genetic section on chromosome 6 (6p21) containing immune recognition genes.²⁰ Many versions of MHC occur among animal species.²⁰
In humans, it is called the HLA complex and contains over 200 genes grouped into class I, II, and III.²⁰
Class I has three major genes, named HLA-A,
HLA-B, and HLA-C.⁷¹ The proteins encoded by these genes are expressed on the surface of most nucleated cells, where they bind to protein fragments (peptides) exported from within the cell.⁷¹ Class I proteins present these peptides to the immune system, and apoptosis is induced if the peptides are recognized as foreign, such as viral or bacterial peptides.⁷¹ Human MHC class II has six main genes, including HLA-DPA1, HLA-DPB1, HLA-DQA1, HLA-DQB1, HLA-DRA, and HLA-DRB1.⁷¹
The proteins produced by these genes are expressed mainly on the surface of certain immune system cells, including B lymphocytes, dendritic cells, macrophages, and activated T lymphocytes.⁷¹ Class II proteins display peptides to the immune system.⁷¹
HLA class I and II genes are highly polymorphic, and inheritance of certain variants may predispose the affected individual to an autoimmune disorder.
Certain HLA class II alleles or combinations of alleles (haplotypes) significantly increase the risk of T1DM, while others confer reduced or protective effects.⁷²
For example, most individuals with T1DM are carriers of either HLA-DR3, DQB1*0201 (also called DR3-DQ2), or DR4-DQB1*0302 (otherwise known as DR4-DQ8).⁷² Also, inheriting the HLA haplotype DRB1*0302-DQA1*0301, particularly when combined with DRB1*0201-DQA1*0501, increases genetic predisposition to T1DM as much as 20-fold.⁷² In contrast, the haplotype DRB1*0602-DQA1*0102 rarely predisposes to T1DM,⁷² while the haplotype HLA-DQ6 (HLA-DQA1*0102-DQB1*0602) is protective.⁶
INS gene
INS gene was the second gene linked with T1DM and accounts for about 10% of T1DM cases.³⁴ It encodes the precursor to insulin, which assists the body to store energy for later use.⁷³ For example, insulin helps the body store glucose as glycogen or fat rather than metabolizing it. Insulin has two separate polypeptide chains, chains A and B, and are connected by disulfide bonds.⁷³
Unlike some proteins that are synthesized by several genes, insulin is synthesized by the
INS gene only. Some animals, such as rats and mice, have two insulin genes but humans only have one. To produce insulin, the
INS gene secretes an inactive insulin precursor called preproinsulin, which is converted to another inactive substance called proinsulin by removal of a signaling peptide.⁷³
Insulin is finally produced from proinsulin by removal of the C-peptide that binds chains
A and B together.⁷³
However, mutations in the
INS gene may disrupt the insulin biosynthetic network, causing some diseases. A point mutation in the
INS gene known as C96Y synthesizes mutant proinsulin, resulting in endoplasmic reticulum (ER) stress, which progressively causes death of β-cells and T1DM.⁷⁴ Several other point mutations have also been reported in individuals and animals with T1DM.The promoter region of the
INS gene is highly polymorphic and contains several variable numbers of tandem repeats (VNTRs), grouped into classes I, II, and III.²⁰ VNTR I contains 26–63 repeats, VNTR II has 80 repeats, and VNTR III has 140–210 repeats. Among Caucasians, VNTR I is highly prevalent, VNTR III is moderately prevalent, while VNTR II is rare. VNTR I homozygotes often develop T1DM than VNTR III, while VNTR II confers a protective effect.²⁰ A polymorphism in the promoter region of the
INS gene determines the regulatory activities of the transcription factor autoimmune regulator on thymic expression of insulin.
The VNTR I allele reduces tolerance to insulin and its precursors, repressing insulin transcription and predisposing the individual to T1DM.²⁰ The VNTR II allele promotes the expression of insulin mRNA in the thymus.²⁰
CTLA4 gene
CTLA4 gene is expressed on the surface of activated T cells, where it attenuates the immune response by binding to ligands CD80 or CD86 expressed on the surface of antigen-presenting cells.⁷⁵
The CTLA4-CD80/CD86 complex represses the IL-2 receptor (CD25), reducing IL-2 synthesis or triggering cell death in already activated cells.⁷⁵ CTLA4 protein also mediates the suppressive activity of CD4+ CD25+ T regulatory cells.⁷⁵
The expression of
CTLA4 in activated T lymphocytes shows that it maintains immune function by preventing the inflammatory response and autoimmunity.⁷⁴
Thus,
CTLA4 plays a negative regulatory role in immune function by preventing the overexpression of T cells. Functional impairment in the
CTLA4 gene may cause overexpression of T cells, causing it to attack self-antigens. Deletion of the Med J Indones mji.ui.ac.id
CTLA4 gene in mice leads to massive proliferation of lymphocytes, resulting in autoimmunity and death.⁷⁴
Several autoimmune disorders have been associated with functional loss or impairment of the
CTLA4 gene. A single nucleotide polymorphism (SNP) +6230G>A characterized by splicing of the gene or altered mRNA is linked with an increased risk for T1DM.⁷⁵
The promoter region of the
CTLA4 gene is polymorphic and a particular SNP −319C>T, which reduces the transcription of the gene, is related to a high risk of T1DM.⁷⁵ SNP involving an A-to-G substitution at nucleotide 49 in exon 1 (G49A), causing an amino acid substitution (Thr17Ala) has also been reported in patients with T1DM.⁷⁵
The predisposing Ala17 allele is partially glycosylated in the ER, resulting in retrograde transport of some molecules into the cytoplasm for lysis,⁷⁵ leading to less
CTLA4 (Ala17) at the cell surface, which may be responsible for loss of function of the
CTLA4 gene expressed by individuals with the +49G allele.⁷⁵ Thus, the G49A allele reduces the negative regulatory role of
CTLA4 and predisposes to TIDM, compared with the 49 G/G alleles, which confers protection.⁷⁴
PTPN22 and
PTPN2 genes
PTPN22 and
PTPN2 genes both code for protein tyrosine phosphatase (PTP) signaling molecules that modulate and regulate several biological processes, including cell growth, survival, and differentiation.⁷⁶
PTPs are important regulators of signaling transduction, as they relay signals from the cell into the nucleus.⁷⁶
Besides cell growth and differentiation, these molecules initiate cell signaling for T cell immune regulatory activities.⁷⁶ PTPs are so important in immune regulation that they are more expressed on immune cells than other body tissues.⁷⁶
A deficiency of PTP in mice distinctively upregulates immune status with severe abnormalities in hematopoiesis, suggesting that PTPs play an important role in maintaining a balanced immune system.⁷⁶
A deficiency in these signaling molecules because of inactivation or loss of
PTPN2 or PTPN22 leads to decreased suppression of the inflammatory response resulting from reduced negative regulation.⁷⁶
PTPN22 is the fourth gene linked with T1DM in which the rs2476601 SNP disrupts PTP intracellular signaling, leading to loss of negative immune regulation.⁷⁵
The SNP causes a single substitution of arginine for tryptophan in the encoded protein (R620W), leading to a decrease in T cell and B cell receptor signaling.⁷⁷
This may disrupt tolerance in both T and B cells, ultimately resulting in diabetes-specific autoimmunity.⁷⁷
The autoimmunity induced by this SNP is characterized by a preponderance of autoreactive B cells and autoantibodies, both of which are biomarkers for the onset and progression of T1DM.⁷⁷
The mechanism for the role of the
PTPN2 gene in the pathogenesis of T1DM is complex, consequent to expression in many cells, but is suspected to involve destruction of pancreatic β-cells.
Functional loss of the
PTPN2 gene may also hamper negative regulation of the apoptotic pathway, leading to overexpression of T cells.
Repression of the
PTPN2 gene impairs insulin production by β-cell s in diabetic mice. In normal individuals,
PTPN2 gene blocks insulin signaling by dephosphorylation of its β-chain receptor with the assistance of PTP1B phosphatase.
This, in turn, controls gluconeogenesis in the liver by suppressing STAT3 signaling and decreasing glucose production.
Mutant
PTPN2 induces mitochondrial apoptotic pathways, resulting in β-cell apoptosis and unbalanced glucose metabolism. A version of
PTPN2 (rs1893217) has been reported to upregulate T cell receptor signaling in mice, causing impaired self-antigen recognition and β-cells destruction consequent to the loss of negative regulation.³⁸
Application of autoantibodies and proteins of T1DM suspect genes as biomarkers
No guidelines have been established for T1DM genetic testing as it is done in DM with monogenetic etiology. This is partly because several genes may interact to cause T1DM and testing for individual genes may not be cost-effective. Also, genetic susceptibility alone may not fully explain the etiology of the disease as environmental triggers, such as diet, infection, and pollutants may play a role in onset of the disease. Nevertheless, the Immunology of Diabetes Society has suggested that certain autoantibodies in individuals with a family history of T1DN may predict the likelihood of the disease. These autoantibodies include islet cell antibodies, insulin autoantibodies, the GAD autoantibody, and the protein tyrosine phosphatase IA-2/ICA512.⁷⁸ Tables 1 and 2 present some genes that produce these autoantibodies. The β-cell function determined by the first-phase insulin response in the intravenous glucose tolerance test can also predict onset of the disease.⁷⁸ The genes whose mutations or variants affect β-cell differentiation and ahaya, et al. | Type 1 diabetes mellitus suspect genes
Medical
Journal of
Indonesia morphology, resulting in loss or reduced functions, are shown in Table 3. The levels of the proteins produced by genes predisposing to enteroviruses, such as B coxsackieviruses, are also a good biomarker of the disease. Notable among these genes are the HLA,
PPTN22 , PPTN2 , and
CTLA4 genes discussed earlier. Abnormal levels of the MHC and CTLA4 proteins could indicate enteroviral induced autoimmunity in T1DM, prompting a therapeutic measure. Viral infection may also raise the concentration of interferons in islet β-cells, which overexpress MHC I, resulting in increased susceptibility to cytotoxic CD8+ T cell recognition and destruction.⁷⁹ Other genes listed earlier whose concentrations are sensitive to viral infections include
ERBB3 , PRKCQ , IL7R , IL2 , TAGAP , IL26 , IL10 , IL12B , and
OAS1 (Table 1).In summary, the reviewed articles indicate that mutations in or variants of certain genes may induce autoimmunity in β-cell s by compromising the immune system, predisposing the carrier to T1DM. Many T1DM predisposing genes have been identified; however, individual genes alone cannot cause the disease. These genes interact with each other, suppressing or overexpressing the functions of one another and may induce DM along with environmental stimuli. These genes initiate DM through different mechanisms, which may result in improved treatment. Healthcare providers are advised to formulate treatment plans that target these genes and mechanisms rather than the current generalized treatment procedure.
Conflict of Interest
The authors affirm no conflict of interest in this study.
Acknowledgment
None.
Funding Sources
None.
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