SOCS signaling in autoimmune diseases: Molecular mechanisms and therapeutic implications

Suppressor of cytokine signaling (SOCS) proteins are mainly induced by various cytokines and have been described as classical inhibitors of cytokine signaling. SOCS signaling is involved in the regulation of immune cells, and recent findings suggest that SOCS proteins, especially SOCS1 and SOCS3, are often dysregulated in a wide variety of autoimmune diseases, including systemic lupus erythematosus, rheumatoid arthritis, type 1 diabetes, psoriasis, and multiple sclerosis. Recent studies suggest that SOCS signaling could be therapeutically targeted in various autoimmune diseases. In this review, we discuss recent studies on the role of SOCS proteins in the development and pathogenesis of autoimmune diseases, as well as their clinical implications.     

NLRP3: A promising therapeutic target for autoimmune diseases

NLRP3, a member of nucleotide-binding domain-(NOD) like receptor family, can be found in large varieties of immune and non-immune cells. Upon activation, the NLRP3, apoptosis-associated speck-like protein (ASC) and pro-caspase-1 would assemble into a multimeric protein, called the NLRP3 inflammasome. Then the inflammasome promotes inflammation (through specific cleavage and production of bioactive IL-1β and IL-18) and pyroptotic cell death. Previous studies have indicated the importance of NLRP3 in regulating innate immunity. Recently, numerous studies have revealed their significance in autoimmune diseases, such as systemic lupus erythematosus (SLE), rheumatoid arthritis (RA), systemic sclerosis (SSc) and inflammatory bowel disease (IBD). In this review, we will briefly discuss the biological features of NLRP3 and summarize the recent progression of the involvement of NLRP3 in the development and pathogenesis of autoimmune diseases, as well as its clinical implications and therapeutic potential.     

Central tolerance and autoimmune diseases]

Central tolerance is established by the repertoire selection of immature T lymphocytes in the thymus, avoiding autoimmune responses to self-antigens. Differential ligand-TCR interactions that result in positive and negative selection initiate differential intracellular signals that, in turn, lead to the survival-or-death decision of immature thymocytes. TCR signal dysregulation due to the mutation of ZAP-70 or defective apoptosis of autoreactive thymocytes due to the deficiency of pro-apoptotic protein Bim impair tolerance and cause autoimmunity. Thymic repertoire selection also induces the development of CD25(+)CD4(+) regulatory T cells, which play important roles for maintaining peripheral tolerance. Furthermore, the establishment of central tolerance requires the development of thymic medulla that is mediated by the activation of NF-kappaB signaling pathway, promiscuous expression of tissue-specific self-antigens by medullary epithelial cells that is regulated by AIRE, and cortex-to-medulla migration of developing thymocytes that is regulated by CCR7-mediated chemokine signals.     

Antibody-mediated neuronal apoptosis: therapeutic implications for prion diseases

Neuronal cell death is considered to be a hallmark in prion diseases. These disorders are believed to result from the post-translational conversion of a normal cell membrane sialoglycoprotein PrPC, composed primarily of alpha-helical structure, into a disease specific isoform, PrPSc that is rich in beta-sheet and partially proteinase-resistant. Recent in vivo studies indicate that prion replication can be inhibited by anti-PrP monoclonal antibodies that led to the indefinite delay in the development of prion disease. The recent report by Solforosi and colleagues has increased the need to understand pathway(s) leading to prion-associated apoptosis and neuronal death thought to be the cause of death in transmissible spongiform encephalopathy (TSE) individuals. Furthermore, these reports increased momentum about the use of antibody-based therapy in prion diseases, although great caution should be exerted when using anti-prion antibodies directly into the central nervous system (CNS) with special emphasis on refined strategies such as specific targeting of regions of the prion protein thought not to be involved in signalling pathways.     

Dendritic cells: vehicles for tolerance induction and prevention of autoimmune diseases

Adaptive immune responses are orchestrated by specialized professional antigen-presenting cells (APCs), the dendritic cells (DCs), which play crucial roles as initiators and modulators of adaptive immune responses. A main feature of DCs is their phenotypic and functional plasticity. In the absence of any inflammation or pathogenic elements, most DCs in peripheral tissues and lymphoid organs have a resting, immature phenotype characterized by high endocytic capacity and low surface expression of MHC- and costimulatory molecules. However, upon interaction with microbial ligands, pro-inflammatory cytokines or CD40Ligand, DCs rapidly acquire an activated phenotype. These mature DCs have a very efficient T cell-priming ability as a consequence of upregulation of MHC- and costimulatory molecules on their cell surface. For this reason, DC-based vaccines have been used successfully to combat infections and malignancies. Nonetheless, evidence is accumulating that, especially immature, or semi-matured, DCs also have a potent ability to tolerize T cells or prevent undesired immune reactions. Therefore, current and prospective strategies to promote the inherent tolerogenic potential of DCs are a rational approach for the therapy of autoimmune diseases such as rheumatoid arthritis (RA). This review summarizes some aspects of the intriguing ability of DCs to steer the outcome of immunity and their potency to modulate the outcome of various pathological conditions.     

Circadian clock genes as promising therapeutic targets for autoimmune diseases

Circadian rhythm is a natural, endogenous process whose physiological functions are controlled by a set of clock genes. Disturbance of the clock genes have detrimental effects on both innate and adaptive immunity, which significantly enhance pro-inflammatory responses and susceptibility to autoimmune diseases via strictly controlling the individual cellular components of the immune system that initiate and perpetuate the inflammation pathways. Autoimmune diseases, especially rheumatoid arthritis (RA), often exhibit substantial circadian oscillations, and circadian rhythm is involved in the onset and progression of autoimmune diseases. Mounting evidence indicate that the synthetic ligands of circadian clock genes have the property of reducing the susceptibility and clinical severity of subjects. This review supplies an overview of the roles of circadian clock genes in the pathology of autoimmune diseases, including BMAL1, CLOCK, PER, CRY, REV-ERBα, and ROR. Furthermore, summarized some circadian clock genes as candidate genes for autoimmune diseases and current advancement on therapy of autoimmune diseases with synthetic ligands of circadian clock genes. The existing body of knowledge demonstrates that circadian clock genes are inextricably linked to autoimmune diseases. Future research should pay attention to improve the quality of life of patients with autoimmune diseases and reduce the effects of drug preparation on the normal circadian rhythms.     

Immunomodulation of experimental autoimmune diseases via oral tolerance

The concept of oral tolerance refers to a form of peripheral tolerance in which mature lymphocytes in the peripheral lymphoid tissues are rendered nonfunctional or hyporesponsive by prior oral administration of an antigen. The primary mechanisms mediating oral tolerance include deletion, anergy of antigen-specific T cells and active cellular suppression, the primary determining factor being the dose of fed antigen. Low doses favor active suppression, whereas high doses favor deletion and anergy. Active cellular suppression is mediated by the induction of regulatory T cells in the gut-associated lymphoid tissue, which migrate to the systemic immune system. One of the primary mechanisms of active cellular suppression is via secretion of suppressive cytokines such as TGF-beta, IL-4, and IL-10 following antigen-specific triggering. TGF-beta is produced both by CD4+ and CD8+ GALT-derived T cells and is an important mediator of the active suppression component of oral tolerance. CD4+ cells that primarily produce TGF-beta appear to be a unique T-cell subset and termed Th3 cells. Oral tolerance was successfully studied in a variety of experimental models for autoimmune diseases, among them experimental autoimmune encephalomyelitis, experimental arthritis, experimental anti-phospholipid syndrome, experimental autoimmune uveoretinitis, experimental insulin dependent diabetes mellitus (IDDM), and experimental autoimmune myasthenia gravis. The results obtained in experimental animal models have led to the conduction of several clinical trials of oral tolerance in patients with multiple sclerosis, rheumatoid arthritis, uveitis, and IDDM. Conflicting results were obtained, and although some improvement has been noted in some of the patients, broad ranging clinical improvement has not yet been observed. A more accurate choice of antigens, as well as more precise dosing and timing of antigen-administration might lead to better results in the future.     

P2X7 receptor: A potential therapeutic target for autoimmune diseases

P2X7 receptor (P2X7R), a distinct ligand-gated ion channel, is a member of purinergic type 2 receptor family with ubiquitous expression in human body. Previous studies have revealed a pivotal role of P2X7R in innate and adaptive immunity. Once activated, it will meditate some vital cascaded responses including the assembly of nucleotide-binding domain (NOD) like receptor protein 3 (NLRP3) inflammasome, non-classical secretion of IL-1β, modulation of cytokine-independent pathways in inflammation such as P2X7R- transglutaminase-2 (TG2) and P2X7R-cathepsin pathway, activation and regulation of T cells, etc. In fact, above responses have been identified to be involved in the development of autoimmunity, specifically, the NLRP3 inflammasome could promote inflammation in massive autoimmune diseases and TG2, as well as cathepsin may contribute to joint destruction and degeneration in inflammatory arthritis. Recently, numerous evidences further suggested the significance of P2X7R in the pathogenesis of autoimmune diseases, including systemic lupus erythematosus (SLE), rheumatoid arthritis (RA), inflammatory bowel disease (IBD), multiple sclerosis (MS), etc. In this review, we will succinctly discuss the biological characteristics and summarize the recent progress of the involvement of P2X7R in the development and pathogenesis of autoimmune diseases, as well as its clinical implications and therapeutic potential.     

Oral tolerance, food allergy, and immunotherapy: implications for future treatment

The lumen of the gastrointestinal tract is exposed daily to an array of dietary proteins. The vast majority of proteins are tolerated through suppression of cellular or humoral responses, a process known as oral tolerance. However, in approximately 6% of children and 4% of adults in the United States, tolerance to a given dietary antigen either is not established or breaks down, resulting in food hypersensitivity. Although food allergies can result in sudden and life-threatening symptoms, their prevalence is remarkably low considering the complexities of the gut-associated mucosal system. Suppression involves signaling by an array of nonprofessional antigen-presenting cells, dendritic cells, and regulatory T cells, as well as lymphocyte anergy or deletion. Several factors, including antigen properties, route of exposure, and genetics and age of the host, contribute to the development of oral tolerance. Although the current standard of care for patients with food allergies is based on avoidance of the trigger, increased understanding of the mechanisms involved in tolerance has shifted focus of treatment and prevention toward inducing tolerance. Data from early-phase clinical trials suggest both sublingual and oral immunotherapy are effective in reducing sensitivity to allergens. In this article we review the mechanisms of tolerance, discuss aberrations in oral tolerance, and provide information on novel prevention and treatment paradigms for food allergy.     

Mesenchymal stem cells as an immunomodulatory therapeutic strategy for autoimmune diseases

Mesenchymal stem cells (MSCs) are non-hematopoietic, multipotent progenitor cells which can be isolated from various human adult tissues. In recent years, MSCs have been shown to possess broad immunoregulatory capabilities, modulating both adaptive and innate immunity. This review discusses the documented immunomodulatory capabilities of the MSCs, the possible mechanisms underlying these functions and presents the potential of using this stem cell-based approach as an immunomodulatory tool for the treatment of autoimmune diseases.     

间充质干细胞移植治疗心血管疾病的应用与进展

背景：间充质干细胞因其具有自我更新、向不同组织分化及免疫调节功能,而被作为治疗急性心肌梗死、心力衰竭等心血管疾病的有效的方法之一。 目的：从间充质干细胞的生物特性,转分化能力、免疫调节、心脏修复的作用机制以及间充质干细胞用于治疗心血管疾病早期的临床实验资料做一简要阐述。 方法：以“间充质干细胞、免疫调控、心肌梗死、心力衰竭”,“MSCs,Immunomodulation,myocardial infarction,heart  failure”为检索词,应用计算机检索维普(VIP)期刊全文数据库及Pubmed 数据库。排除与研究目的无关和内容重复者。保留35篇文献做进一步分析。 结果与结论：间充质干细胞作为理想的种子细胞,除了具备自我更新、多向分化潜能之外,还具有免疫调节功能,避免同种异体移植或异种移植引起的免疫排斥反应。它可以向心肌细胞及脉管系统分化,通过旁分泌作用分泌一系列的细胞活素类物质及生长因子,并且动员内在的心肌干细胞,从而起到改善心功能,诱导逆向重塑,降低心梗面积的作用。相关的临床实验也显示了移植间充质干细胞的可行性和有效性。     

Dendritic cell vaccine design: strategies for eliciting peripheral tolerance as therapy of autoimmune diseases

Dendritic cells (DC), as potent antigen-presenting cells (APC), constitute a complex system of cells that initiate and regulate immune responses that result in two opposite outcomes: immunity or tolerance. The fine regulation of these two distinct functions is not completely understood. After loading with antigen, DC exhibit the properties of both antigen and adjuvant, the functional components of vaccines. For a long time, attention has focused on the exceptional ability of DC as professional APC capable of eliciting T and B cell-mediated responses, and on their potential as immunotherapy in cancer. DC exhibit both heterogeneity and plasticity. On the one hand, distinct DC subsets exhibit distinct functions. On the other hand, DC functions can be altered by the cytokine environment or other factors. There is increasing evidence that DC could be used as a tool to induce peripheral tolerance. Because DC-based immunotherapy in autoimmune diseases depends on tolerogenic DC, discerning markers for tolerogenic DC is of great importance. Immature DC, plasmacytoid DC and interleukin-10-modified DC can mediate immune tolerance by inducing T-cell anergy or T-helper type 2 responses. Several possibilities exist for rational modulation of DC to achieve therapeutic tolerance against autoimmune diseases. The final goal is to create optimal prerequisites to use autologous DC that are prepared from the individual patient with autoimmune disease, to render such DC tolerogenic by exposure in vitro to factors that promote tolerogenicity, and to re-infuse these pretreated DC to the patient in order to treat the ongoing autoimmune disease and prevent its future exacerbation.     

CCR6-CCL20 axis as a therapeutic target for autoimmune diseases

Chemokine receptor CCR6 is expressed on various cells such as B cells, immature dendritic cells, innate lymphoid cells (ILCs), regulatory CD4 T cells, and Th17 cells. CCL20 is the only known high-affinity ligand that binds to CCR6 and drives CCR6⁺ cells' migration in tissues. CCL20 is mainly produced by epithelial cells, and its expression is increased by several folds under inflammatory conditions. Genome-wide association studies (GWAS) in patients with inflammatory bowel disease (IBD), psoriasis (PS), rheumatoid arthritis (RA), and multiple sclerosis (MS) showed a very strong correlation between the expression of CCR6 and disease severity. It has been shown that disruption of CCR6-CCL20 interaction by using antibodies or antagonists prevents the migration of CCR6 expressing immune cells at the site of inflammation and reduces the severity of the disease. This review discussed the importance of the CCR6-CCL20 axis in IBD, PS, RA, and MS, and recent advances in targeting the CCR6-CCL20 in controlling these autoimmune diseases.     

Potentiation of immunological tolerance induction in adult mice by co-administration of pooled normal IgG and oral tolerogens: a potential therapeutic approach for autoimmune diseases

Oral tolerance can be defined as the inability of an adult animal to produce specific antibodies or cellular immune responses upon conventional immunization, after oral antigenic administration. Recently, the oral administration of antigens has gained renewed interest because of the possibility of inducing tolerance in nonimmunized adult animals and, consequently, opening up the theoretical possibility of preventing or treating diseases caused by malfunction of the immune system. This strategy has been proven to be useful in the prevention of allergic and autoimmune diseases in rodents, as well as in the amelioration of certain autoimmune diseases in humans. Although there is experimental and clinical evidence for the usefulness of oral tolerance in medical practice, the mechanisms responsible for this phenomenon are still poorly understood, and the results obtained are not always satisfactory. Herein, we show that the thymus is required for the induction and maintenance of oral tolerance, providing evidence that it is not a pure form of clonal deletion-based peripheral tolerance. Oral tolerance could therefore depend on the formation and release to the periphery of regulatory T cells, such as gammadelta or alphabeta T cells, by the thymus. This finding may have profound implications for the treatment of autoimmune diseases, since most of them are associated with thymic hypofunction. On the other hand, due to so far unknown mechanisms, the intraperitoneal co-administration of normal IgG to mice orally treated with tolerogen leads to a sustained and intense immunological tolerance, both in euthymic and thymectomized mice, including those of the lupus erythematosus-prone NZB x NZW lineage. This approach for inducing and maintaining tolerance in thymus-deficient conditions is discussed and put forth herein as a new evidence-based proposition for the therapy of autoimmune diseases.     

Regulation and dysregulation of Epstein-Barr virus latency: implications for the development of autoimmune diseases

Epstein-Barr virus (EBV) is a human herpesvirus hiding in a latent form in memory B cells in the majority of the world population. Although, primary EBV infection is asymptomatic or causes a self-limiting disease, infectious mononucleosis, the virus is associated with a wide variety of neoplasms developing in immunosuppressed or immunodeficient individuals, but also in patients with an apparently intact immune system. In memory B cells, tumor cells, and lymphoblastoid cell lines (LCLs, transformed by EBV in vitro) the expression of the viral genes is highly restricted. There is no virus production (lytic viral replication associated with the expression of all viral genes) in tight latency. The expression of latent viral oncogenes and RNAs is under a strict epigenetic control via DNA methylation and histone modifications that results either in a complete silencing of the EBV genome in memory B cells, or in a cell-type dependent usage of latent promoters in tumor cells, germinal center B cells, and LCLs. Both the latent and lytic EBV proteins are potent immunogens and elicit vigorous B- and T-cell responses. In immunosuppressed and immunodeficient patients, or in individuals with a functional defect of EBV-specific T cells, lytic EBV replication is regularly activated and an increased viral load can be detected in the blood. Enhanced lytic replication results in new infection events and EBV-associated transformation events, and seems to be a risk factor both for malignant transformation and the development of autoimmune diseases. One may speculate that an increased load or altered presentation of a limited set of lytic or latent EBV proteins that cross-react with cellular antigens triggers and perpetuates the pathogenic processes that result in multiple sclerosis, systemic lupus erythematosus (SLE), and rheumatoid arthritis. In addition, in SLE patients EBV may cause defects of B-cell tolerance checkpoints because latent membrane protein 1, an EBV-encoded viral oncoprotein can induce BAFF, a B-cell activating factor that rescues self-reactive B cells and induces a lupus-like autoimmune disease in transgenic mice.     

The evolution and breakdown of the immune system: implications for development of autoimmune diseases

At the most recent meeting of the Scandinavian Society for Immunology in Bergen, one of the major target phenomena was autoimmune diseases. The approach started from the evolutionary origins of immunity, went on to review some of the notable advances in molecular architecture of immune processes and finally focussed the findings on autoimmune disease.     

Novel, non-antigen-specific therapeutic approaches to autoimmune/inflammatory diseases

Anti-TNF therapy has made a major impact on the treatment of inflammatory arthritides and Crohn's disease. It leads to prompt and prolonged clinical response, even in patients refractory to conventional therapy. Moreover, the progression of joint damage noted in patients with rheumatoid arthritis treated with methotrexate was prevented by an anti-TNF-alpha antibody, suggesting a genuine disease-modifying potential of TNF-alpha blockade.