Interferon type I
|Interferon Type I (α/β/δ...)|
|SCOP2||1au1 / SCOPe / SUPFAM|
The type-I interferons (IFN) are cytokines which play essential roles in inflammation, immunoregulation, tumor cells recognition, and T-cell responses. In the human genome, a cluster of thirteen functional IFN genes is located at the 9p21.3 cytoband over approximately 400 kb including coding genes for IFNα (IFNA1, IFNA2, IFNA4, IFNA5, IFNA6, IFNA7, IFNA8, IFNA10, IFNA13, IFNA14, IFNA16, IFNA17 and IFNA21), IFNω (IFNW1), IFNɛ (IFNE), IFNк (IFNK) and IFNβ (IFNB1), plus 11 IFN pseudogenes. 
Sources and functions
IFN-α and IFN-β are secreted by many cell types including lymphocytes (NK cells, B-cells and T-cells), macrophages, fibroblasts, endothelial cells, osteoblasts and others. They stimulate both macrophages and NK cells to elicit an anti-viral response, involving IRF3/IRF7 antiviral pathways, and are also active against tumors. Plasmacytoid dendritic cells have been identified as being the most potent producers of type I IFNs in response to antigen, and have thus been coined natural IFN producing cells.
IFN-ω is released by leukocytes at the site of viral infection or tumors.
IFN-α acts as a pyrogenic factor by altering the activity of thermosensitive neurons in the hypothalamus thus causing fever. It does this by binding to opioid receptors and eliciting the release of prostaglandin-E2 (PGE2).
In mice, IFN-β inhibits immune cell production of growth factors, thereby slowing tumor growth, and inhibits other cells from producing vessel producing growth factors, thereby blocking tumor angiogenesis and hindering the tumour from connecting into the blood vessel system.
In both mice and human, negative regulation of type I interferon is known to be important. Few endogenous regulators have been found to elicit this important regulatory function, such as SOCS1 and Aryl Hydrocarbon Receptor Interacting Protein (AIP).
The mammalian types are designated IFN-α (alpha), IFN-β (beta), IFN-κ (kappa), IFN-δ (delta), IFN-ε (epsilon), IFN-τ (tau), IFN-ω (omega), and IFN-ζ (zeta, also known as limitin). Of these types, IFN-α, IFN -ω, and IFN-τ can work across species.
The IFN-α proteins are produced mainly by plasmacytoid dendritic cells (pDCs). They are mainly involved in innate immunity against viral infection. The genes responsible for their synthesis come in 13 subtypes that are called IFNA1, IFNA2, IFNA4, IFNA5, IFNA6, IFNA7, IFNA8, IFNA10, IFNA13, IFNA14, IFNA16, IFNA17, IFNA21. These genes are found together in a cluster on chromosome 9.
IFN-α is also made synthetically as medication in hairy cell leukemia. The International Nonproprietary Name (INN) for the product is interferon alfa. The recombinant type is interferon alfacon-1. The pegylated types are pegylated interferon alfa-2a and pegylated interferon alfa-2b.
The IFN-β proteins are produced in large quantities by fibroblasts. They have antiviral activity that is involved mainly in innate immune response. Two types of IFN-β have been described, IFN-β1 (IFNB1) and IFN-β3 (IFNB3) (a gene designated IFN-β2 is actually IL-6). IFN-β1 is used as a treatment for multiple sclerosis as it reduces the relapse rate.
IFN-β1 is not an appropriate treatment for patients with progressive, non-relapsing forms of multiple sclerosis.
IFN-ε, -κ, -τ, -δ and -ζ
IFN-ε, -κ, -τ, and -ζ appear, at this time, to come in a single isoform in humans, IFNK. Only ruminants encode IFN-τ, a variant of IFN-ω. So far, IFN-ζ is only found in mice, while a structural homolog, IFN-δ is found in a diverse array of non-primate and non-rodent placental mammals. Most but not all placental mammals encode functional IFN-ε and IFN-κ genes.
IFN-ω, although having only one functional form described to date (IFNW1), has several pseudogenes: IFNWP2, IFNWP4, IFNWP5, IFNWP9, IFNWP15, IFNWP18, and IFNWP19 in humans. Many non-primate placental mammals express multiple IFN-ω subtypes.
This subtype of type I IFN was recently described as a pseudogene in human, but potentially functional in the domestic cat genome. In all other genomes of non-feline placental mammals, IFN-ν is a pseudogene; in some species, the pseudogene is well preserved, while in others, it is badly mutilated or is undetectable. Moreover, in the cat genome, the IFN-ν promoter is deleteriously mutated. It is likely that the IFN-ν gene family was rendered useless prior to mammalian diversification. Its presence on the edge of the type I IFN locus in mammals may have shielded it from obliteration, allowing its detection.
Interferon type I in Cancer
From the 1980s onward, members of type-I IFN family have been the standard care as immunotherapeutic agents in cancer therapy. In particular, IFNα has been approved by the US Food and Drug Administration (FDA) for cancer. To date, pharmaceutical companies produce several types of recombinant and pegylated IFNα for clinical use; e.g., IFNα2a (Roferon-A, Roche), IFNα2b (Intron-A, Schering-Plough) and pegylated IFNα2b (Sylatron, Schering Corporation) for treatment of hairy cell leukemia, melanoma, renal cell carcinoma, Kaposi's sarcoma, multiple myeloma, follicular and non-Hodgkin lymphoma, and chronic myelogenous leukemia. Human IFNβ (Feron, Toray ltd.) has also been approved in Japan to treat glioblastoma, medulloblastoma, astrocytoma, and melanoma.
Copy number alteration of the interferon gene cluster in cancer
A large individual patient data meta-analysis using 9937 patients obtained from cBioportal indicates that copy number alteration of the IFN gene cluster is prevalent among 24 cancer types. Notably deletion of this cluster is significantly associated with increased mortality in many cancer types particularly uterus, kidney, and brain cancers. The Cancer Genome Atlas PanCancer analysis also showed that copy number alteration of the IFN gene cluster is significantly associated with decreased overall survival. For instance, the overall survival of patients with brain glioma reduced from 93 months (diploidy) to 24 months. In conclusion, the copy number alteration of the IFN gene cluster is associated with increased mortality and decreased overall survival in cancer. 
Avian type I IFNs have been characterized and preliminarily assigned to subtypes (IFN I, IFN II, and IFN III), but their classification into subtypes should await a more extensive characterization of avian genomes.
Functional lizard type I IFNs can be found in lizard genome databases.
Turtle type I IFNs have been purified (references from 1970s needed). They resemble mammalian homologs.
The existence of amphibian type I IFNs have been inferred by the discovery of the genes encoding their receptor chains. They have not yet been purified, or their genes cloned.
Piscine (bony fish) type I IFN has been cloned first in zebrafish. and then in many other teleost species including salmon and mandarin fish. With few exceptions, and in stark contrast to avian and especially mammalian IFNs, they are present as single genes (multiple genes are however seen in polyploid fish genomes, possibly arising from whole-genome duplication). Unlike amniote IFN genes, piscine type I IFN genes contain introns, in similar positions as do their orthologs, certain interleukins. Despite this important difference, based on their 3-D structure these piscine IFNs have been assigned as Type I IFNs. While in mammalian species all Type I IFNs bind to a single receptor complex, the different groups of piscine type I IFNs bind to different receptor complexes. Until now several type I IFNs (IFNa, b, c, d, e, f and h) has been identified in teleost fish with as low as only one subtype in green pufferfish and as many as six subtypes in salmon with an addition of recently identified novel subtype, IFNh in mandarin fish.
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