Risk Factors for the Health of the Population of an Industrial City and Their Impact on Regional Features of Inflammatory Diseases

Increasing evidence implicates circulating platelets as mediators of chronic inflammatory and autoimmune diseases via the expression and release of CD40L, an important modulator of inflammation and adaptive immune responses traditionally associated with activated T cells. Emerging evidence suggests that platelet CD40L is dynamically regulated in several chronic inflammatory and autoimmune diseases and may mediate progression and secondary pathology associated with those disease states. The present study identifies NFATc2 as a key transcriptional modulator of CD40L expression in megakaryocytes and inflammatory activity of platelets. Furthermore, the current data show that EGR-1, a member of the early growth response family of zinc finger transcription factors, modulates NFATc2-dependent regulation of CD40L expression in megakaryocytes. Our novel demonstration that in vivo biochemical or genetic inhibition of NFATc2 activity in megakaryocyte diminishes platelet CD40L implicates the NFATc2/EGR-1 axis as a key regulatory pathway of inflammatory and immunomodulatory activity in platelets and represents a target for the development of therapeutics for the potential treatment of chronic inflammatory and autoimmune diseases.

Crosstalk between type II NKT cells and T cells leads to spontaneous chronic inflammatory liver disease

Regulatory T Cells: Key Controllers of Immunologic Self-Tolerance

T-cell mediated immune responses should be regulated to avoid the development of autoimmune or chronic inflammatory diseases. Several mechanisms have been described to regulate this process, namely death of overactivated T cells by cytokine deprivation, suppression by T regulatory cells (Treg), induction of expression of immune checkpoint molecules such as CTLA-4 and PD-1, or activation-induced cell death (AICD). In addition, activated T cells release membrane microvesicles called exosomes during these regulatory processes. In this review, we revise the role of exosome secretion in the different pathways of immune regulation described to date and its importance in the prevention or development of autoimmune disease. The expression of membrane-bound death ligands on the surface of exosomes during AICD or the more recently described transfer of miRNA or even DNA inside T-cell exosomes is a molecular mechanism that will be analyzed.

Therapeutic advances using targeted biologicals and small-molecule drugs have achieved significant success in the treatment of chronic allergic, autoimmune, and inflammatory diseases particularly for some patients with severe, treatment-resistant forms. This has been aided by improved identification of disease phenotypes. Despite these achievements, not all severe forms of chronic inflammatory and autoimmune diseases are successfully targeted, and current treatment options, besides allergen immunotherapy for selected allergic diseases, fail to change the disease course. T cell-based therapies aim to cure diseases through the selective induction of appropriate immune responses following the delivery of engineered, specific cytotoxic, or regulatory T cells (Tregs). Adoptive cell therapies (ACT) with genetically engineered T cells have revolutionized the oncology field, bringing curative treatment for leukemia and lymphoma, while therapies exploiting the suppressive functions of Tregs have been developed in nononcological settings, such as in transplantation and autoimmune diseases. ACT with Tregs are also being considered in nononcological settings such as cardiovascular disease, obesity, and chronic inflammatory disorders. After describing the general features of T cell-based approaches and current applications in autoimmune diseases, this position paper reviews the experimental models testing or supporting T cell-based approaches, especially Treg-based approaches, in severe IgE-mediated responses and chronic respiratory airway diseases, such as severe asthma and COPD. Along with an assessment of challenges and unmet needs facing the application of ACT in these settings, this article underscores the potential of ACT to offer curative options for patients with severe or treatment-resistant forms of these immune-driven disorders.

NOD.H-2h4 mice: an important and underutilized animal model of autoimmune thyroiditis and Sjogren's syndrome.

Parvovirus B19 infection has been associated with various clinical entities including musculoskeletal manifestations and the development of different autoimmune diseases. The aim of our study is to examine the musculoskeletal manifestations associated with acute parvovirus B19 infection and the possible development of chronic autoimmune rheumatic diseases. Retrospective cohort study that included adult hospitalized patients diagnosed with an acute parvovirus B19 infection between 1 January 2021 and 1 February 2024. Subjects were followed-up for 6-12 months after hospitalization aiming to identify patients who developed chronic autoimmune rheumatic diseases. The study included 23 patients diagnosed with acute parvovirus B19 infection. Patients were predominantly females (16, 69.6%) with mean age at diagnosis of 39.3 ± 13.11 years. Most patients were Jewish (15, 65.2%). The two most common acute symptoms were fever (82.6%) and myalgia (56.5%). Polyarthritis was present only in three patients (13%) and all of them had wrists involvement. Anti-nuclear antibodies and rheumatoid factor were the most common autoantibodies present with equal prevalence each (13%). Five patients were treated with prednisone during the acute phase (21%), two (8.7%) of them needed drug escalation and were subsequently treated with hydroxychloroquine and methotrexate. One patient developed systemic lupus erythematosus during the first 6 months of follow-up. Musculoskeletal manifestations developing during acute parvovirus B19 are usually self-limited with only a small minority of patients developing chronic autoimmune diseases. It is crucial to differentiate self-limited manifestations related to acute parvovirus B19 from idiopathic autoimmune diseases aiming to avoid unnecessary immunosuppressive therapy.

Atherosclerosis is a chronic inflammatory disease characterized by accumulation of oxidized lipoproteins, increased cell death and hypertrophic degeneration of the arterial intima. The disease process is associated with local formation of modified self antigens that are targeted by both innate and adaptive immune responses. Although it remains to be firmly established it is likely that these autoimmune responses initially have a beneficial effect facilitating the removal of potentially harmful rest products from oxidized LDL and dying cells. However, studies performed on hypercholesterolaemic mice deficient in different components of the immune system uniformly suggest that the net effect of immune activation is pro-atherogenic and that atherosclerosis, at least to some extent, should be regarded as an autoimmune disease. These observations point to the possibility of developing new treatments for atherosclerosis based on modulation of immune responses against plaque antigens, an approach presently tested clinically for several other chronic inflammatory diseases with autoimmune components. Pilot studies in animals have provided promising results for both parental and oral vaccines based on oxidized LDL antigens. The time when this concept is ready for clinical testing is rapidly approaching but it will be important not to underestimate the difficulties that will be encountered in transferring the promising results from experimental animals into humans.

Synthesis of benzoxazole derivatives as interleukin-6 antagonists

This study systematically review knowledge about the mechanisms of formation of an inflammatory reaction under the influence of biological, physical, and chemical factors, their similarities and differences, and possible methods of pharmacological correction of pathological conditions associated with excessive activation. The effect of adverse environmental factors, such as biological, physical, and chemical factors, causes a systemic response, which is aimed at maintaining homeostasis and is caused, among other things, by a coordinated reaction of the immune system. Phlogogenic agents result in the activation and regulation of the inflammatory response, which is formed by cellular and humoral components of innate immunity. The activation of innate immunity is characterized by a rapid host response, which diminishes following the elimination of foreign invaders, endogenous killer cells, and neogenesis. Depending on the nature of the active factors (biopathogens, allergens, toxins, ionizing radiation, etc.), the mechanisms of immune response arousal have unique features mainly originating from the differences in the recognition of specific molecular patterns and danger signals by different receptors. However, inflammatory mediators and inflammatory response patterns at the systemic level are largely similar even under widely different triggers. Inflammation, having evolved as an adaptive reaction directed at the immune response, can lead to the development of chronic inflammation and autoimmune diseases due to a mismatch in mechanisms of its control. A failure in the regulation of the inflammatory process is the excessive activation of the immune system, which leads to the cytokine release syndrome (hypercytokinemia, or cytokine storm) and can cause self-damage (destruction) of tissues, multiple-organ failure, sepsis, and even death. Modern advances in the study of the pathogenetic bases of the inflammatory response are suggested, such as pharmacological correction using pattern recognition receptor antagonists, pro-inflammatory cytokine inhibitors, or blocking of key control genes or signaling pathways.

ABSTRACTThe immune system provides protection to tissues damaged by infectious microrganisms or physical damage. In autoimmune diseases, the immune system recognizes and attacks its own tissues, i.e., self-destruction. Various agents such as genetic factors and environmental triggers are thought to play a major role in the development of autoimmune diseases. A common feature of all autoimmune diseases is the presence of autoantibodies and inflammation, including mononuclear phagocytes, autoreactive T lymphocytes, and autoantibody producing B cells (plasma cells). It has long been known that B cells produce autoantibodies and, thereby, contribute to the pathogenesis of many autoimmune diseases. Autoimmune diseases can be classified as organ-specific or non-organ specific depending on whether the autoimmune response is directed against a particular tissue or against widespread antigens as in chronic inflammatory autoimmune diseases such as systemic lupus erythematosus (SLE) and rheumatoid arthritis (RA). Both SLE and RA are characterized by the presence of autoantibodies which play a major role in their etiopathogenesis. SLE is characterized by circulating antibodies and immune complex deposition that can trigger an inflammatory damage in organs. RA is a progressive inflammatory disease in which T cells, B cells, and pro-inflammatory cytokines play a key role in its pathophysiology.

Obesity Drives Th17 Cell Differentiation by Inducing the Lipid Metabolic Kinase, ACC1

Role of CD154 in cancer pathogenesis and immunotherapy

Interleukin (IL)-23 is a central pro-inflammatory cytokine with a broad range of effects on immune responses. IL-23 is pathologically linked to the induction of the production of the pro-inflammatory cytokines IL-17 and IL-22, which stimulate the differentiation and proliferation of T helper type 17 (Th17) cells. Recent discoveries suggest a potential pro-fibrotic role for IL-23 in the development of chronic inflammatory autoimmune diseases characterized by intense fibrosis. In this review, we summarized the biological features of IL-23 and gathered recent research on the role of IL-23 in fibrotic autoimmune conditions, which could provide a theoretical basis for clinical targeting and drug development.

Blocking DCIR mitigates colitis and prevents colorectal tumors by enhancing the GM-CSF-STAT5 pathway.