activation

Activation of cells of the immune system variably induces proliferation, differentiation, production, and maturation. Some activated cells of the immune system are involved in activation (costimulation) of other cell types. Likewise, some activated cells express molecules involved in activation.

▼ activating agents : B cell activation : costimulatory agents : costimulatory cells : complement activation pathways : dendritic cell activation : granulocyte activation : lymphocyte activation : macrophage alternative : macrophage classical : markers : mediators : monocyte-macrophage : pDC : phagocyte activation : precursor dendritic cells : signaling/receptors : T cell activation : Tc activation : Th activation ▼

Activating agents
_ ● antigen
___ ● pathogens
___ ● pathogen-associated molecular patterns (PAMP)
___ ● danger-associated molecular patterns (DAMP)

Markers
___ ● major histocompatibility complex (MHC) molecules

Costimulatory agents
___ ● CD28
___ ● SLAM (signaling lymphocytic activation molecule), a 70-kDa costimulatory molecule belonging to the Ig superfamily
___ ● ICOS (inducible costimulator) molecules
___ ● TNFR: CD40, CD30, CD27, OX-40, 4-1BB
___ ● negative regulators of costimulation: CTLA-4, PD-1

Costimulatory cells
● helper T cells (Th) for activation of B cells, and APCs for activation of T cells
_ ● Antigen presenting cells display epitope proteins – exogenous antigen or fragmented antigen from phagocytosed cells – on their surfaces. APCs include:
___ ● phagocytic cells – dendritic cells, macrophages
___ ● B cells (B lymphocytes)

Signaling / receptors
_ ● pattern recognition receptors
_____ ● complement receptors (table)
_____ ● Fc receptors (table)
_____ ● scavenger receptors (table)
_____ ● Toll-like receptors (table)
_ ● TNFR
_ ● B cell receptors (BCR)
___ ● immunoglobulin - antibodies (table)
_ ● T cell receptors (TCR)
_____ ● clusters of differentiation
_____ ● major histocompatibility complex (MHC) molecules

Mediators
_ ● immune cytokines (table)

Phagocytes

Dendritic cells
Dendritic cells and their immature counterparts, Langerhans cells (LC), are highly specialized, professional antigen-presenting cells (APC). Immature dendritic cells are called 'veiled cells' because they display large cytoplasmic 'veils' rather than the long dendritic projections of mature cells. As key regulators of immune responses, dendritic cells (DC) stimulate lymphocytes to perform cell-mediated and humoral immune responses against pathogens and tumor cells.

Immature, precursor dendritic cells (pDC) circulate throughout the body, migrating to lymphocyte rich tissues (such as spleen and lymph nodes) upon stimulating encounter with antigen. The dendritic cells internalize the antigen then externalize (fragmented) antigen that they present to lymphocytes in MHC-peptide complexes, expressing markers that stimulate lymphocyte activation.

Monocyte → macrophage activation
Production of the macrophage lineage from progenitors in the bone marrow is typically controlled by M-CSF, which is constitutively expressed by many cell types. Serum levels of M-CSF and GM-CSF increase in response to invasive stimuli and inflammation, and monocyte numbers increase dramatically. M-CSF-derived macrophages are larger, and have a higher phagocytic capacity, while GM-CSF-derived macrophages are more cytotoxic against TNF-α-resistant tumour targets, express more MHC class II antigen, and constitutively secrete more PGE-2.

Classically activated macrophages are associated with chronic inflammation and tissue injury wherein classically activated macrophages exhibit a Th1-like phenotype, promoting inflammation, destruction of the extracellular matrix (ECM), and apoptosis. Classical macrophage activation proceeds in two stages.
1. IFN-γ-primed stage in which macrophages exhibit enhanced MHC class II expression, antigen presentation, but reduced proliferative capacity. (IFN-α, IFN-β, IL-3, M-CSF, GM-CSF and TNF-α can also prime macrophages for selected functions.)
2. Secondary stimuli operated to fully activate primed macrophages. Diverse agents provide secondary signals (including LPS (CD14), bacteria, yeast glucans, GM-CSF and phorbol esters). Macrophages stimulated for tumoricidal activity secrete IL-1, display decreased MHC class II gene transcription, and are generally poor antigen presenters of antigen.[r]

Alternatively activated macrophages typically resolve inflammation and facilitate wound healing wherein they display a Th2-like phenotype, promoting construction of ECM, cell proliferation, and angiogenesis. Alternative macrophage activation does not require a priming stage and IL-42 and/or IL-1326 can act as sufficient stimuli.[r2]

Granulocyte activation
The hematopoietic cytokines, granulocyte colony-stimulating factor (G-CSF) and granulocyte-macrophage colony-stimulating factor (GM-CSF) have pleiotropic activating effects on mature leukocytes, which can improve leukocyte function, facilitating eradication of microbial infections. G-CSF activates neutrophils, while GM-CSF activates neutrophils, eosinophils, and monocyte/macrophages.

Lymphocytes
B cell activation: naïve B cells → plasma cells
Activation of naïve B cells occurs when a BCR (antibody) encounters and ligates its cognate antigen. B cells are coated in immunoglobulin receptors and are able to recognize intact antigen, which they engulf, digest, and subsequently present in complex with surface MHC class II molecules. The MHC-peptide complex binds CD4 + helper T cells (Th), inducing secretion of cytokines that stimulate B cell proliferation and their differentiation into plasma cells, which secrete specific antibodies that bind with the cognate antigen. These antigen-antibody complexes are subsequently cleared by liver and spleen cells and the classical complement cascade.

T cell activation:
Activation of T cells requires a first signal of TCR engagement, which ensures antigen specificity and MHC restriction of the response. The second signal comprises synergistic costimulatory signaling by professional antigen presenting cells. The costimulatory second signal is necessary to sustain and integrate TCR signaling to stimulate optimal T cell proliferation and differentiation. The level of activation of T cells is closely related to their state of differentiation.

Activation of the resting Tc cell involves two steps: 1) TCR on the CD8+ cell interacts with antigen-class I MHC complex on the surface of a target cell. 2) CD8+ Tc cell is stimulated by cytokines, particularly IL-2, which have been secreted predominantly by activated Th cells. Resting Tc do not express IL-2 receptors until antigen stimulation increases the expression of Tc IL-2 receptors, ensuring that activation is confined to Tc cells that ligate cognate antigen. Activated Tc cells become CTLs.

The first signal for helper T cell (Th) activation is interaction of the TcR-CD3 complex with antigen-MHC class II molecules on the surface of an antigen presenting cell. Stimulation is aided by the CD4 molecule on Th cells, with or without assistance from other accessory molecules, such as CD45, CD28 and CD2. Increased IL-2 secretion by the T cell and an increase in IL-2 receptors on the T cell surface trigger a cascade of biochemical events.



Three pathways are involved in complement activation:
● classical pathway (binding of an antibody to its cognate antigen)
● alternative pathway (relies upon spontaneous conversion of C3 to C3b)
● mannose-binding lectin pathway (MBL -MAPS) (homologous to the classical pathway, but utilizes opsonin, mannan-binding lectin (MBL) and ficolins rather than C1q)

▲ф A activating agents § adaptor protein ~ adhesion molecules ф affinity maturation ♦ AID ф anergy ф antibodies ф antigen ф APCs סּ apoptosis ф autoimmunity B : B cell activation ф B cells ọ blood ọ bone marrow C סּ caspases ф CD סּ cell-cycle control ₪ cellular fate ф cellular response סּ cellular signal transduction סּ chemotaxis ф class-switch recombination ф clonal selection ф complement system : complement activation pathways : costimulatory agents : costimulatory cells ~ cytokines ~ cytokine receptors D סּ death receptor : dendritic cell activation ф dendritic cells ₪ differentiation E סּ ECM F ♦ Fyn G ф gene conversion ọ germinal centers : granulocyte activation ф granulocytes H ф helper T cell ф hematopoiesis ф humoral immunity I ф immune cytokines ф immune response ф immune tolerance ~ immunoglobulins § immunoglobulin isotypes ф inflammatory response ф interferons ф isotype switching L ф leukocytes ф leukocyte adhesion cascade : lymphocyte activation ф lymphocytes ọ lymphoid system ф lymphokines ф lymphoid system M : macrophage alternative : macrophage classical ф macrophages ф MHC ф migration ¤ mitogens ф monocytes : markers : mediators : monocyte-macrophage N § NF-κB P ф pathogens ф pattern-recognition receptors : pDC : phagocyte activation ф phagocyte ф plasma cells : precursor dendritic cells ¤ proliferation R ф receptors S ф secondary antibody diversification ф signaling ¤ signaling molecules : signaling/receptors סּ signal transduction ф somatic hypermutation, somatic mutation ф surface receptors T : T cell activation ф T cells : Tc activation : Th activation ф thymus ọ thymus ф (tolerance) ▲ф


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tags [Immunology] [activation]

APCs

APCs are antigen presenting cells, which display epitope proteins – exogenous antigen or fragmented antigen from phagocytosed cells – on their surfaces.

▼ APC types : B cells : BCRs : CD1 family : CD1 proteins : CD4+ : class II MHC : dendritic cells : endocytosis : exocytosis : fragmented antigen peptides : histocompatibility molecules : γδ T cells : intact antigen : lipid antigen : macrophages : mycobacterial cell wall components : peptide antigen : phagocytic presenting cells : T cells and fragmented peptides, T cells and lipid antigens ▼

Antigen presenting cells include:
● phagocytic cells – dendritic cells, macrophages
● B cells (B lymphocytes)
● γδ T cells

Fragmented antigen – APCs engulf the antigen through endocytosis, then the endosome fuses with a lysosome where the antigen is digested into fragments such as short peptides. Following, exocytosis, a class II histocompatibility molecule holds the fragmented antigenic peptides at the surface of the cell, where they may be recognized by CD4+ T cells.

Intact antigen – dendritic cells can present intact antigen to B cells (not fragmented in lysosomes) by presenting the antigen on the cell surface. This antigen can bind to BCRs of the appropriate specificity, and can stimulate the B cells.

Presentation of peptide antigens for activation of naïve T cells does not reside solely in dendritic cells. A population of γδ T cells can efficiently present peptide antigens to αβT cells, and γδ T cells of the major tissue subset recognize self and foreign nonpeptide, lipid antigens presented by CD1 proteins. γδ T cells carry TCRs encoded by different gene segments than those of αβ T cells.

CD1 proteins are a family (CD1a-e) of cluster of differentiation glycoproteins related to the class I MHC molecules. CD1 are involved in the presentation of lipid and glycolipid antigens, particularly self, microbial, and mycobacterial cell wall components, to CD1-specific T cells.

The human CD1 family of transmembrane glycoproteins are encoded by five CD1 family genes organized in a cluster on chromosome 1. CD1 glycoproteins form heterodimers with beta-2-microglobulin. CD1 family members are considered to differ in cellular localization and specificity for particular lipid ligands. The CD1a protein (R4, T6, CD1, FCB6, HTA1) localizes to the plasma membrane and to recycling vesicles of the early endocytic system. Alternatively spliced transcript variants have been observed.[e]

ф activation ₪ alternative splicing ф antibodies ф antigen ф B cells cell membranes ф costimulation ф dendritic cells סּ endosomes סּ exosome ф helper T cell ф killer T cells סּ lysosome ф macrophages ф MHC ф pathogens ф pattern-recognition receptors ф phagocyte סּ phagocytosis סּ receptor-mediated endocytosis ф surface receptors ф γδ T cells ф T cells

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tags [Immunology][APC]

cellular response

Cellular responses to invading pathogens utilize phagocytic and cytotoxic cells of the innate and adaptive immune responses.

The immune system is intimately connected with the hematologic system since white blood cells (leukocytes, including B- and T-lymphocytes) are key players in the lymphoid system.
Cellular participants in the immune and inflammatory responses include :
● phagocytic cells (dendritic cells, monocytes and macrophages, and granulocytes)
● antigen presenting cells (dendritic cells, macrophages, B lymphocytes, helper T cells, γδ T cells)
● antibody producing cells (plasma cells)
● cytotoxic cells (CTL, NK)
● regulatory cells (APCs, helper T cells, regulatory T cells)
● cells-in-waiting (memory B cells, monocytes)
● chemical releasing cells (basophils, eosinophils, neutrophils; mast cells - histamine, cytokines; hepatocytes - complement proteins)

Innate responses solely comprise cellular immune responses employ phagocytic cells that are circulating or tissue emplaced – granulocytes, monocytes, dendritic cells, macrophages, natural killer T cells, and B lymphocytes. The innate response induces (triggers) the adaptive system, the cellular component of which relies upon activated macrophages, T-lymphocytes – cytotoxic T lymphocytes (killer T cells).

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tags [Immunology][cellular+immunity]