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Cytokines are a group of proteins and peptides that are used in organisms as signaling compounds. These chemical signals are similar to hormones and neurotransmitters and are used to allow one cell to communicate with another. The cytokine family consists mainly of smaller water-soluble proteins and glycoproteins (proteins with an added sugar chain) with a mass of 8-30 kDa. While hormones are released from specific organs into the blood and neurotransmitters are released by nerves, cytokines are released by many types of cells. They are particularly important in both innate and adaptive immune responses. Due to their central role in the immune system, cytokines are involved in a variety of immunological, inflammatory and infectious diseases. However, not all their functions are limited to the immune system, as they are also involved in several developmental processes during embryogenesis.
Cytokines are produced by a wide variety of cell types (both haemopoietic and non-haemopoietic) and can have effects on both nearby cells or throughout the organism. Sometimes these effects are strongly dependent on the presence of other chemicals and cytokines.
Each cytokine binds to a specific cell-surface receptor. Subsequent cascades of intracellular signalling then alter cell functions. This may include the upregulation and/or downregulation of several genes and their transcription factors, in turn resulting in the production of other cytokines, an increase in the number of surface receptors for other molecules, or the suppression of their own effect by feedback inhibition.
The effect of a particular cytokine on a given cell depends on the cytokine, its extracellular abundance, the presence/abundance of the complementary receptor on the cell surface, and downstream signals activated by receptor binding; these last two factors can vary by cell type. Interestingly, cytokines are characterized by considerable "redundancy", in that many cytokines appear to share similar functions.
Generalization of functions is not possible with cytokines; nonetheless, their actions may be comfortably grouped as:
- autocrine, if the cytokine acts on the cell that secretes it
- paracrine, if the action is restricted to the immediate vicinity of a cytokine's secretion
- endocrine, if the cytokine diffuses to distant regions of the body (carried by blood or plasma) to affect different tissues.
Cytokines binding to antibodies paradoxically have a stronger immune effect than the cytokine alone. This may lead to lower therapeutic doses and perhaps fewer side effects.
Cytokines have been variously named as lymphokines, interleukins and chemokines, based on their presumed function, cell of secretion or target of action. Because cytokines are characterized by considerable redundancy and pleiotropism, such distinctions, allowing for exceptions, are obsolete.
- The term interleukin was initially used by researchers for those cytokines whose presumed targets are principally leukocytes. It is now used largely for designation of newer cytokine molecules discovered every day and bears little relation to their presumed function.
- The term chemokine referred to a specific class of cytokines that mediated chemoattraction (chemotaxis) between cells.
Of note, IL-8 (interleukin-8) is the only chemokine originally named an interleukin.
Structural homology has been able to partially distinguish between cytokines that do not demonstrate a considerable degree of redundancy so that they can be classified into four types:
- The four α-helix bundle family - Member cytokines have three-dimensional structures with four bundles of α-helices. This family in turn is divided into three sub-families: erythropoietin (EPO) and thrombopoietin (THPO). Alternatively, four α-helix bundle cytokines can be grouped into long chain and short chain cytokines.
- the IL-1 family - It primarily includes IL-1 and IL-18.
- the IL-17 family - It has yet to be completely characterized, though member cytokines have a specific effect in promoting proliferation of T-cells that cause cytotoxic effects.
A more clinically and experimentally useful classification divides immunological cytokines into those that promote the proliferation and functioning of helper T-cells, type 1 ( IFN-γ etc.) and type 2 (IL-4, IL-10, IL-13, TGF-β etc.), respectively.
A key focus of interest has been that cytokines in one of these two sub-sets tend to inhibit the effects of those in the other. This tendency is under intensive study for its possible role in the pathogenesis of autoimmune disorders.
Cytokine receptors Edit
In recent years, the cytokine receptors have come to demand the attention of more investigators than cytokines themselves, partly because of their remarkable characteristics, and partly because a deficiency of cytokine receptors have now been directly linked to certain debilitating immunodeficiency states. In this regard, and also because the redundancy and pleiomorphism of cytokines are in fact a consequence of their homologous receptors, many authorities are now of the opinion that a classification of cytokine receptors would be more clinically and experimentally useful.
A classification of cytokine receptors based on their three-dimensional structure has therefore been attempted. (It must be noted that such a classification, though seemingly cumbersome, provides with several unique perspectives for attractive pharmacotherapeutic targets.)
- Immunoglobulin (Ig) superfamily, which are ubiquitously present throughout several cells and tissues of the vertebrate body, and share structural homology with immunoglobulins (antibodies), cell adhesion molecules, and even some cytokines. Examples: IL-1 receptor types.
- Haemopoietic Growth Factor (type 1) family, whose members have certain conserved motifs in their extracellular amino-acid domain. The IL-2 receptor belongs to this chain, whose γ-chain (common to several other cytokines) deficiency is directly responsible for the x-linked form of Severe Combined Immunodeficiency (X-SCID).
- Interferon (type 2) family, whose members are receptors for IFN β and γ.
- Tumour Necrosis Factor (TNF) (type 3) family, whose members share a cysteine-rich common extracellular binding domain, and includes several other non-cytokine ligands like CD40, CD27 and CD30, besides the ligands on which the family is named (TNF).
- Seven transmembrane helix family, the ubiquitous receptor type of the animal kingdom. All G-protein coupled receptors (for hormones and neurotransmitters) belong to this family. It is important to note that chemokine receptors, two of which act as binding proteins for HIV (CXCR4 and CCR5), also belong to this family.
Cysteine-knot cytokines Edit
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- Gallin J, Snyderman R (eds). Inflammation: Basic Principles and Clinical Correlates. 3rd edition, Philadelphia, Lippincott William and Wilkins, 1999.
- Janeway CA et al. (eds). Immunobiology. The immune system in Health and Disease, 4th edition, New York, Garland, 1999.
- Roitt I et al. (eds.) Immunology. 5th edition, London, Mosby, 2002.
- Science Vol. 311 No. 5769, pp. 1875 - 1876, 31 March 2006 DOI: 10.1126/science.1126030
See also Edit
- Cytokine secretion assay
- Cytokine storm
- ELISA assays
- ELISPOT assays
- Granulocyte-colony stimulating factor
- Signal transduction
- Tumor necrosis factor
- Cytokine Tutorial
- Cell Interactions: Cytokines
- Reperfusion Injury in Stroke.
- Cytokines Online Pathfinder Encyclopaedia
- Cytokines and inflammation, science and practical journal
Cell physiology: cell signaling
|Types of proteins|
Immune system / Immunology / Psychoneuroimmunology
|Systems||Adaptive immune system vs. Innate immune system • Humoral immune system vs. Cellular immune system • Complement system (Anaphylatoxins)|
|Antibodies and antigens||Antibody (Monoclonal antibodies, Polyclonal antibodies, Autoantibody) • Allotype • Isotype • Idiotype • Antigen (Superantigen)|
|Immune cells||White blood cells (T cell, B cell, NK cell, Mast cell, Basophil, Eosinophil) • Phagocyte (Neutrophil, Macrophage, Dendritic cell) • Antigen-presenting cell • Reticuloendothelial system|
|Immunity vs. tolerance||Immunity • Autoimmunity • Allergy • Tolerance (Central) • Immunodeficiency|
|Immunogenetics||Somatic hypermutation • V(D)J recombination • Immunoglobulin class switching • MHC / HLA|
|Other||Cytokines • Inflammation • Opsonin|
Cell signaling: cytokines
Autocrine motility factor - Chemokine - Hematopoietic (Stem cell factor, Colony-stimulating factor) - Hepatocyte growth factor - Interferon - Interleukin - Leukemia inhibitory factor - Lymphokine (Lymphotoxin, Transfer factor) - Monokine - Oncostatin M - Osteopontin - TGF beta - Tumor necrosis factor
CCL1 - CCL2 - CCL3 - CCL4 - CCL5 - CCL6 - CCL7 - CCL8 - CCL9 - CCL10 - CCL11 - CCL12 - CCL13 - CCL14 - CCL15 - CCL16 - CCL17 - CCL18 - CCL19 - CCL20 - CCL21 - CCL22 - CCL23 - CCL24 - CCL25 - CCL26 - CCL27 - CCL28
|IL-6 like/gp130 utilizing|
|Interferon type III|
|Common Gamma-c family|
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