Splenic role in the regulation of immune responses.

Evidence for a splenic role in regulating antibody production in other lymphoid tissue was obtained in a system in which cyclical fluctuations of splenic plaque-forming cells (PFC) occur following a single intravenous injection of aggregated human γ-globulin in rabbits. First, PFC arising simultaneously in the mesenteric nodes, peripheral blood, and spleen appear to be derived from the spleen since splenectomy prior to antigen injection abrogated these responses. Second, a noncyclical appearance of PFC in popliteal nodes of rabbits responding to subcutaneous injection of antigen was converted to a cyclical response by simultaneous intravenous injection of antigen, an effect which was abolished by splenectomy prior to antigen injection. It is suggested that, following an intravenous injection of antigen, both suppressor cells as well as antibody-forming precursors may be activated in the spleen and disseminated to other lymphoid tissue.     

Modeling systems-level regulation of host immune responses

Many pathogens are able to manipulate the signaling pathways responsible for the generation of host immune responses. Here we examine and model a respiratory infection system in which disruption of host immune functions or of bacterial factors changes the dynamics of the infection. We synthesize the network of interactions between host immune components and two closely related bacteria in the genus Bordetellae. We incorporate existing experimental information on the timing of immune regulatory events into a discrete dynamic model, and verify the model by comparing the effects of simulated disruptions to the experimental outcome of knockout mutations. Our model indicates that the infection time course of both Bordetellae can be separated into three distinct phases based on the most active immune processes. We compare and discuss the effect of the species-specific virulence factors on disrupting the immune response during their infection of naive, antibody-treated, diseased, or convalescent hosts. Our model offers predictions regarding cytokine regulation, key immune components, and clearance of secondary infections; we experimentally validate two of these predictions. This type of modeling provides new insights into the virulence, pathogenesis, and host adaptation of disease-causing microorganisms and allows systems-level analysis that is not always possible using traditional methods.     

Negative regulation of toll-like receptor-mediated immune responses

Toll-like receptors (TLRs) are involved in host defence against invading pathogens, functioning as primary sensors of microbial products and activating signalling pathways that induce the expression of immune and pro-inflammatory genes. However, TLRs have also been implicated in several immune-mediated and inflammatory diseases. As the immune system needs to constantly strike a balance between activation and inhibition to avoid detrimental and inappropriate inflammatory responses, TLR signalling must be tightly regulated. Here, we discuss the various negative regulatory mechanisms that have evolved to attenuate TLR signalling to maintain this immunological balance.     

Ubiquitin enzymes in the regulation of immune responses

Ubiquitination plays a central role in the regulation of various biological functions including immune responses. Ubiquitination is induced by a cascade of enzymatic reactions by E1 ubiquitin activating enzyme, E2 ubiquitin conjugating enzyme, and E3 ubiquitin ligase, and reversed by deubiquitinases. Depending on the enzymes, specific linkage types of ubiquitin chains are generated or hydrolyzed. Because different linkage types of ubiquitin chains control the fate of the substrate, understanding the regulatory mechanisms of ubiquitin enzymes is central. In this review, we highlight the most recent knowledge of ubiquitination in the immune signaling cascades including the T cell and B cell signaling cascades as well as the TNF signaling cascade regulated by various ubiquitin enzymes. Furthermore, we highlight the TRIM ubiquitin ligase family as one of the examples of critical E3 ubiquitin ligases in the regulation of immune responses.     

Anaphylatoxin-mediated regulation of human and murine immune responses

C3a and C5a derived from the human complement components C3 and C5, respectively, were found to possess immunoregulatory activities. C3a was found to be capable of suppressing both antigen-specific and polyclonal antibody responses. In contrast, C3a was unable to suppress antigen- or mitogen-induced B or T cell proliferative responses. Helper T cells were found to be the target of C3a-mediated immunosuppression. Suppression occurred via the generation of suppressor T cells. In contrast to the results obtained with C3a, C5a was found to augment both antigen-specific and non-specific in vitro humoral immune responses. Moreover, C5a potentiated antigen- and alloantigen-induced T cell proliferative responses. As opposed to C3ades Arg-77, C5ades Arg retained all of the immunoregulatory activity associated with the intact molecule. Helper T cells are required for C5a-mediated potentiation of the Fc fragment-mediated polyclonal antibody response. Substitution for T cells by a soluble T cell-replacing factor rendered lymphocytes refractory to the enhancing properties of C5a.     

Mitochondrial DNA in the regulation of innate immune responses

Mitochondrion is known as the energy factory of the cell, which is also a unique mammalian organelle and considered to be evolved from aerobic prokaryotes more than a billion years ago. Mitochondrial DNA, similar to that of its bacterial ancestor’s, consists of a circular loop and contains significant number of unmethylated DNA as CpG islands. The innate immune system plays an important role in the mammalian immune response. Recent research has demonstrated that mitochondrial DNA (mtDNA) activates several innate immune pathways involving TLR9, NLRP3 and STING signaling, which contributes to the signaling platforms and results in effector responses. In addition to facilitating antibacterial immunity and regulating antiviral signaling, mounting evidence suggests that mtDNA contributes to inflammatory diseases following cellular damage and stress. Therefore, in addition to its well-appreciated roles in cellular metabolism and energy production, mtDNA appears to function as a key member in the innate immune system. Here, we highlight the emerging roles of mtDNA in innate immunity.     

Osteopontin: role in immune regulation and stress responses

Recent research has led to a better but as yet incomplete understanding of the complex roles osteopontin plays in mammalian physiology. A soluble protein found in all body fluids, it stimulates signal transduction pathways (via integrins and CD44 variants) similar to those stimulated by components of the extracellular matrix. This appears to promote the survival of cells exposed to potentially lethal insults such as ischemia/reperfusion or physical/chemical trauma. OPN is chemotactic for many cell types including macrophages, dendritic cells, and T cells; it enhances B lymphocyte immunoglobulin production and proliferation. In inflammatory situations it stimulates both pro- and anti-inflammatory processes, which on balance can be either beneficial or harmful depending on what other inputs the cell is receiving. OPN influences cell-mediated immunity and has been shown to have Th1-cytokine functions. OPN deficiency is linked to a reduced Th1 immune response in infectious diseases, autoimmunity and delayed type hypersensitivity. OPN's role in the central nervous system and in stress responses has also emerged as an important aspect related to its cytoprotective and immune functions. Evidence suggests that either OPN or anti-OPN monoclonal antibodies (depending on the circumstances) might be clinically useful in modulating OPN function. Manipulation of plasma OPN levels may be useful in the treatment of autoimmune disease, cancer metastasis, osteoporosis and some forms of stress.     

Defective regulation of immune responses in respiratory syncytial virus infection

The relationship of suppressor cell numbers and function to virus-specific IgE response was determined in 72 infants with respiratory syncytial virus (RSV) infection. Monoclonal antibodies to membrane antigens were used to enumerate OKT4 and OKT8 antigen-positive cells, and suppressor cell function as quantitated by the degree of suppression of lymphocyte mitogenesis induced by incubation of lymphocyte cultures with histamine. Patients with bronchiolitis had fewer OKT8-positive cells during convalescence than patients with other forms of illness due to RSV (p less than 0.05). An inverse correlation of OKT8-positive cell numbers and peak IgE titers was observed (p less than 0.01). Histamine-induced suppression was also reduced in patients with bronchiolitis (p less than 0.05). In patients with repeated infection, improved histamine-induced suppression was associated with reduced virus-specific IgE titers and the absence of wheezing. Defects in immunoregulation may underlie previously recognized immunologic and pharmacologic abnormalities in patients with bronchiolitis.     

Coordinate regulation of immune and inflammatory responses by T cell-derived lymphokines

In response to antigenic stimulation, helper T cells secrete a set of protein mediators called lymphokines that regulate proliferation, differentiation, and maturation of lymphocytes and hemopoietic cells. Because all known lymphokines are composed of a single polypeptide chain, their coding sequences can be isolated by functional expression in appropriate host cells. Based on this expression cloning protocol, a number of T cell lymphokine genes have been isolated, their primary structure has been determined, and biological properties of their recombinant products have been examined. These studies revealed the existence of a regulatory network between lymphoid cells and hemopoietic cells mediated by the actions of multiple pleiotropic lymphokines produced by activated T cells. Because all or a part of this network can be activated in different ways by unique combinations of lymphokines, it is clear that T cells can play a vital role in coordinating the function of different body compartments in the immune and inflammatory responses. The activation of lymphokine genes in T cells by antigen is rapid and temporal. Therefore, an inflammatory response that involves proliferation and maturation of target cells may be restricted to the site of lymphokine production. This inducible hemopoiesis appears to be differentially regulated from the steady state or constitutive hemopoiesis that occurs in the bone marrow microenvironment in the absence of immunological stimuli.