The Cellular and Molecular Bases of Allergy, Inflammation and Tissue Fibrosis in Patients with IgG4-related Disease
Abstract
:1. Introduction
2. Genetic Predisposition in Patients with IgG4-RD
3. Intestinal Dysbiosis in Animal Model and Patients with IgG4-RD
3.1. Induction of AIP by Persistent Exposure to Intestinal Commensal Flora Antigens in Animal Models
3.2. Intestinal Dysbiosis-mediated AIP
4. Autoantibody Diversity in Patients with IgG4-RD
5. Development of IgG4 Antibodies by Modified Th2 Response
5.1. Modified Th2 Response for the Class-switch from IgE to IgG4
5.2. Odd Immunological Properties of IgG4 Antibody
5.2.1. Fab–arm Exchange Between 2 Different IgG4 Antibodies Resulting in Non-inflammatory Properties of IgG4 Antibody
5.2.2. A Unique Conformation of FG Loop in the CH2 Domain of IgG4 Molecule
5.2.3. Rheumatoid Factor-like Fc Binding Activity of IgG4 in the Autoimmune and Inflammatory Pathology
5.2.4. Pathologic Roles of IgG4-autoantibodies in Certain Autoimmune Diseases
5.2.5. The Glycosylation Patterns of IgG4 Molecule Induce Complement Activation in Some IgG4-RD Patients with Hypocomplementemia and Primary Sclerosing Cholangitis
6. Eosinophilia, Hyper-IgE Levels and Allergy in Patients with IgG4-RD
7. The Pathogenic Role of B Cells in Chronic Inflammation and Storiform Fibrosis in Patients with IgG4-RD
7.1. The Pathogenic Roles of CD19+ Plasmablasts in AIP Patients
7.2. The Ontogenesis of MFBs
7.3. The Fibrosis-related Inflammatory Mediators
7.4. Pathogenic Roles of B Cell Subsets, B Cell-derived Factors and Help Signals in the Tissue Fibrosis of Patients with IgG4-RD
8. The Cellular and Molecular Bases of Allergy, Inflammation and Tissue Fibrosis in Patients with IgG4-RD
8.1. Involvement of Innate Immune Cells in Patients with IgG4-RD
8.2. The Immunopathologic Roles of Aberrant Functions of Treg, Tfh and CD4+ and CD8+Tc Subsets in Patients with IgG4-RD
8.3. Involvement of Abnormally Functioning Bre FliC g cells in Patients with IgG4-RD
9. Conclusions
10. Future Prospects
- The precise epigenetic regulations, including DNA methylation/acetylation and histone modifications for the diverse immune dysfunctions in IgG4-RD;
- The aberrant expression of non-coding RNAs in the ontogenesis of abnormal B cell biology in IgG4-RD;
- The characterization of factors involved in the induction of CD4+Tc in IgG4-RD;
- The elucidation of the sophisticated molecular mechanism underlying storiform fibrosis;
- Clarification of the interactions between H. pylori infection and other environmental factors, such as allergens for development of the disease;
- Immunopathologic roles of different IgG4 autoantibodies in its pathogenesis;
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
AID | activation-induced cytidine deaminase |
AIP | autoimmune pancreatitis |
AIT | allergen-induced immunotherapy |
APC | antigen presenting cell |
APRIL | a proliferation-inducing ligand |
BAFF B | B lymphocyte-activating factor of tumor necrosis factor family |
Bφ | basophil |
Breg | regulatory B lymphocyte |
C | complement component |
CA | pancreatic carbonic anhydrase |
CCL | C-C chemokine motif ligand |
CD | cluster of differentiation |
CP | chronic pancreatitis |
CTGF | connective tissue growth factor |
CXCL | C-X-C chemokine motif ligand |
CXCR | C-X-C chemokine receptor |
DAMP | damage associated molecular pattern |
EC | endothelial cell |
Eφ | eosinophil |
FB | fibroblast |
FcγR | Immunoglobulin G fragment C gamma receptor |
FGFBP2 | fibroblast growth factor binding protein 2 |
FliC | flagellin |
GC | germinal center |
GWAS | genome-wide association study |
HLA | human leukocyte antigen |
H. pylori | Helicobacter pylori |
IgG4-RD | IgG4-related disease |
IFN | interferon |
IL | interleukin |
IRF-7 | interferon regulatory factor-7 |
K | lysine |
LF | lactoferrin |
LOXL2 | lysyl oxidase-like 2 |
MAMP | microbe-associated molecular pattern |
mCRP | monomeric C-reactive protein |
MFB | myofibroblast |
MMP | matrix metalloproteinase |
MST | mammalian STE20-like protein kinase |
Mφ | macrophage |
NLR | nucleotide-binding oligomerization domain like receptor |
P | proline |
PAMP | pathogen-associated molecular pattern |
PBMC | peripheral blood mononuclear cell |
PBP | plasminogen-binding protein |
pDC | plasmacytoid dendritic cell |
PDGF | platelet-derived growth factor |
PDGFB | platelet-derived growth factor B |
PMN | polymorphonuclear neutrophil |
Q | glutamine |
R | arginine |
RT-PCR | reverse transcriptase assisted polymerase chain reaction |
S | serine |
SIPS | systemic IgG4-related plasmacytic syndrome |
SLAMF7 | signaling lymphocytic activation molecule F7 |
SLE | systemic lupus erythematosus |
SNP | single nucleotide polymorphism |
SPINK1 | serine peptidase inhibitor, Kazal type 1 |
PST1 | pancreatic secretary trypsin inhibitor-1 |
PRSS1 | protease serine 1 (trypsin 1) |
ST2 | suppression of tumorigenicity 2 |
Tc | cytotoxic T lymphocyte |
TCN1 | transcobalamin 1 |
TEM | T cells with effector memory phenotype |
Tfh | follicular helper T cell |
TGF | transforming growth factor |
Th | helper T lymphocyte |
TIMP | tissue inhibitor of matrix metalloproteinase |
TLR | Toll-like receptor |
Treg | regulatory T lymphocyte |
UBR2 | ubiquitin–protein ligase E3 component n-region 2 |
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(1) Clinical manifestations [1,2,3,4,5,6,7,8] | |
Type 1 autoimmune pancreatitis | IgG4-related pachymeningitis |
IgG4-related dacryoadenitis | IgG4-related hypophysitis |
IgG4-related sialoadenitis | IgG4-related aortitis/periaortitis/arteritis /mediastinitis/mesenteritis |
Küttner’s tumor (submandibular sialodenitis) | IgG4-related pleuritis/pericarditis |
Mikulicz’s disease (sialoadenitis +dacryoadenitis) | InG4-related mastitis |
IgG4-related orbital myositis | Ormond’s disease (retroperitoneal fibrosis) |
Riedel’s thyroiditis | IgG4-related membranous glomerulonephritis |
IgG4-related allergic rhinitis | IgG4-related ureteritis/urethritis |
IgG4-related asthma | IgG4-related prostatitis |
IgG4-related chronic rhinosinusitis | IgG4-related skin diseases |
IgG4-related lung disease / pseudotumor | IgG4-related lymphadenopathy IgG4-related midline destruction lesion |
IgG4-related sclerosing cholangitis | |
IgG4-related cholecystitis | |
IgG4-related hepatitis | |
(2) Characteristic histopathologicalfeatures [9,10,11,12] | |
Lymphoplasmacytic infiltration: IgG4 (+) plasma cell/IgG (+) plasma cell ratio >40% | |
Storiform fibrosis: irregular whorled organization of the collagen bundles throughout the tissue led by the activation of myofibroblasts after profibrotic stimuli of inflammation | |
Eosinophil, but not neutrophil infiltration, is commonly present Absence of granuloma or tissue necrosis | |
Obliterative phlebitis: partial or complete obliteration of medium-sized veins by lymphoplasmacytic cell infiltration appearing as an inflammatory nodule next to a patent artery |
(1) Genetic loci |
KLF7, FRMD4B, LOC101928923, MPPED2 in Japanese AIP associated with lacrimal/salivary gland lesions [14] Decreased MST1 of regulatory T in Japanese AIP with extra-pancreatic lesions [17] |
FGFBP2 (fibroblast growth factor binding protein type 2): single base deletion in IgG4-RD [19] |
(2) Persistent exposure of intestinal commensal flora antigen in mouse AIP model |
Avirulent E. coli (as PAMP activator) induces anti-CA II, anti-LF and ANA in mouse AIP with salivary gland involvement [20] |
Commensal E. coli-derived membrane protein flagellin (FliC) induces AIP-like inflammation in mouse model [21] |
Intestinal microflora can activate TLRs and NLRs on basophils to promote Th2 skewing and IgG4 production in the presence of BAFF [22,23,24,25,26] |
(3) Intestinal dysbiosis-mediated AIP development via pDC activation |
Decrease in gut Bacteroides, Streptococcus and Clostridium species in patients with AIP, compared to chronic pancreatitis [28] |
Activation of pDC by innate immune responses against intestinal dysbiosis in experimental mouse AIP [29] |
Anti-carbonic anhydrase II [33,34,35] |
Anti-carbonic anhydrase I [33] and IV [36] |
Anti-pancreatic secretary trypsin inhibitor-1 (PST1) [37] |
Anti-plasminogen-binding protein (PBP) of H. pylori [38] |
Anti-pancreatic trypsinogens PRSS1 and PRSS2 [39] |
Anti-13.1 kDa protein in systemic IgG4-related plasmacytic syndrome (SIPS) [40] |
Anti-amylase-2A [41] |
Anti-prohibitin [42,43] |
Anti-galectin-3 [43,45] |
Anti-annexin A11 [43,46] |
Anti-laminin 511-E8 [43,47] |
Anti-monomeric C-reactive protein (mCRP) in acute interstitial nephritis [48] |
Parameters | IgE | IgG4 |
---|---|---|
Class-switch by | IL-4, IL-13 [52] | IL-4, IL-13 [52], IL-10 |
Enhanced secretion by | IL-5, IL-6, IL-7, IL-9 & IL-13 [52,55,57] | IL-10 [56], IL-21 [58,59,60] |
Surface receptor binding | FcγR on mast cells and basophils | Low binding to FcγR on immune cells [51,66,67] |
Precipitating immune complexes formation | (+) | (-) [61,62,66,67] |
Complement activation | (+) | (-) [62,66,67] |
Unique immunological effects | Allergic reaction | Anti-allergen antibody [51,53,54,64] |
Therapeutic application | Anti-cancer IgE antibody [54] | Non-inflammatory monoclonal antibody [57,62,63,64,65,73] |
IgG4 antibodies undergo a process of “Fab–arm exchange” to become half-antibodies with monovalency incapable of C1q activation and with low binding affinity to FcγRII and FcγRIII resulting in non-inflammatory property [51,62,67,68,69,70,71,72,73] |
Anti-allergic effect by attenuation of Th2 cytokine-mediated inflammation and immunosuppression [51,53,54,63,72] |
Exhibition of rheumatoid factor-like activity by Fc–Fc aggregation to resume activating complements [51,75] |
IgG4 obtained from IgG4-RD subjects binds to normal epithelial cells of pancreato–hepatobiliary tissues and salivary glands in vitro [49] |
Pathologic effects in certain autoimmune diseases including pemphigus foliaceus, muscle-specific kinase myasthenia gravis (MuSK MG) and idiopathic membranous nephropathy [76,77,78,79,80] |
Complement activation and hypocomplementemia in IgG4-RD with unique-pattern glycosylation [81,82,83,84,85,86] |
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Hsieh, S.-C.; Shen, C.-Y.; Liao, H.-T.; Chen, M.-H.; Wu, C.-H.; Li, K.-J.; Lu, C.-S.; Kuo, Y.-M.; Tsai, H.-C.; Tsai, C.-Y.; et al. The Cellular and Molecular Bases of Allergy, Inflammation and Tissue Fibrosis in Patients with IgG4-related Disease. Int. J. Mol. Sci. 2020, 21, 5082. https://doi.org/10.3390/ijms21145082
Hsieh S-C, Shen C-Y, Liao H-T, Chen M-H, Wu C-H, Li K-J, Lu C-S, Kuo Y-M, Tsai H-C, Tsai C-Y, et al. The Cellular and Molecular Bases of Allergy, Inflammation and Tissue Fibrosis in Patients with IgG4-related Disease. International Journal of Molecular Sciences. 2020; 21(14):5082. https://doi.org/10.3390/ijms21145082
Chicago/Turabian StyleHsieh, Song-Chou, Chieh-Yu Shen, Hsien-Tzung Liao, Ming-Han Chen, Cheng-Han Wu, Ko-Jen Li, Cheng-Shiun Lu, Yu-Min Kuo, Hung-Cheng Tsai, Chang-Youh Tsai, and et al. 2020. "The Cellular and Molecular Bases of Allergy, Inflammation and Tissue Fibrosis in Patients with IgG4-related Disease" International Journal of Molecular Sciences 21, no. 14: 5082. https://doi.org/10.3390/ijms21145082
APA StyleHsieh, S. -C., Shen, C. -Y., Liao, H. -T., Chen, M. -H., Wu, C. -H., Li, K. -J., Lu, C. -S., Kuo, Y. -M., Tsai, H. -C., Tsai, C. -Y., & Yu, C. -L. (2020). The Cellular and Molecular Bases of Allergy, Inflammation and Tissue Fibrosis in Patients with IgG4-related Disease. International Journal of Molecular Sciences, 21(14), 5082. https://doi.org/10.3390/ijms21145082