IRF4

Lua error in Module:Infobox_gene at line 53: attempt to index field 'wikibase' (a nil value). Interferon regulatory factor 4 (IRF4) also known as MUM1 is a protein that in humans is encoded by the IRF4 gene.^[1][2][3] IRF4 functions as a key regulatory transcription factor in the development of human immune cells.^[4][5] The expression of IRF4 is essential for the differentiation of T lymphocytes and B lymphocytes as well as certain myeloid cells.^[4] Dysregulation of the IRF4 gene can result in IRF4 functioning either as an oncogene or a tumor-suppressor, depending on the context of the modification.^[4]

The MUM1 symbol is also the current HGNC official symbol for melanoma associated antigen (mutated) 1 (HGNC:29641).

IRF4 is a transcription factor belonging to the Interferon Regulatory Factor (IRF) family of transcription factors.^[4][5] In contrast to some other IRF family members, IRF4 expression is not initiated by interferons; rather, IRF4 expression is promoted by a variety of bioactive stimuli, including antigen receptor engagement, lipopolysaccharide (LPS), IL-4, and CD40.^[4][5] IRF4 can function either as an activating or an inhibitory transcription factor depending on its transcription cofactors.^[4][5] IRF4 frequently cooperates with the cofactors B-cell lymphoma 6 protein (BCL6) and nuclear factor of activated T-cells (NFATs).^[4] IRF4 expression is limited to cells of the immune system, in particular T cells, B cells, macrophages and dendritic cells.^[4][5]

IRF4 plays an important role in the regulation of T cell differentiation. In particular, IRF4 ensures the differentiation of CD4⁺ T helper cells into distinct subsets.^[4] IRF4 is essential for the development of T_h2 cells and T_h17 cells. IRF4 regulates this differentiation via apoptosis and cytokine production, which can change depending on the stage of T cell development.^[5] For example, IRF4 limits production of Th2-associated cytokines in naïve T cells while its upregulates the production of Th2 cytokines in effector and memory T cells.^[4] While not essential, IRF4 is also believed to play a role in CD8⁺ cytotoxic T cell differentiation through its regulation of factors directly involved in this process, including BLIMP-1, BATF, T-bet, and RORγt.^[4] IRF4 is necessary for effector function of T regulatory cells due to its role as a regulatory factor for BLIMP-1.^[4]  

IRF4 is an essential regulatory component at various stages of B cell development. In early B cell development, IRF4 functions alongside IRF8 to induce the expression of the Ikaros and Aiolos transcription factors, which decrease expression of the pre-B-cell-receptor.^[5] IRF4 then regulates the secondary rearrangement of κ and λ chains, making IRF4 essential for the continued development of the BCR.^[4]

IRF4 also occupies an essential position in the adaptive immune response of mature B cells. When IRF4 is absent, mature B cells fail to form germinal centers (GCs) and proliferate excessively in both the spleen and lymph nodes.^[5] IRF4 expression commences GC formation through its upregulation of transcription factors BCL6 and POU2AF1, which promote germinal center formation.^[6] IRF4 expression decreases in B cells once the germinal center forms, since IRF4 expression is not necessary for sustained GC function; however, IRF4 expression increases significantly when B cells prepare to leave the germinal center to form plasma cells.^[5]

Long-lived plasma cells are memory B cells that secrete high-affinity antibodies and help preserve immunological memory to specific antigens.^[7] IRF4 plays a significant role at multiple stages of long-lived plasma cell differentiation. The effects of IRF4 expression are heavily dependent on the quantity of IRF4 present.^[6] A limited presence of IRF4 activates BCL6, which is essential for the formation of germinal centers, from which plasma cells differentiate.^[7] In contrast, elevated expression of IRF4 represses BCL6 expression and upregulates BLIMP-1 and Zbtb20 expression.^[7] This response, dependent on a high dose of IRF4, helps initiate the differentiation of germinal center B cells into plasma cells.^[7]

IRF4 expression is necessary for isotype class switch recombination in germinal center B cells that will become plasma cells. B cells that lack IRF4 fail to undergo immunoglobulin class switching.^[5] Without IRF4, B cells fail to upregulate the AID enzyme, a component necessary for inducing mutations in immunoglobulin switch regions of B cell DNA during somatic hypermutation.^[5] In the absence of IRF4, B cells will not differentiate into Ig-secreting plasma cells.^[5]

IRF4 expression continues to be necessary for long-lived plasma cells once differentiation has occurred. In the absence of IRF4, long-lived plasma cells disappear, suggesting that IRF4 plays a role in regulating molecules essential for the continued survival of these cells.^[7]

Among myeloid cells, IRF4 expression has been identified in dendritic cells (DCs) and macrophages.^[4][5]

The transcription factors IRF4 and IRF8 work in concert to achieve DC differentiation.^[4][5] IRF4 expression is responsible for inducing development of CD4+ DCs, while IRF8 expression is necessary for the development of CD8+ DCs.^[5] Expression of either IRF4 or IRF8 can result in CD4-/CD8- DCs.^[5] Differentiation of DC subtypes also depends on IRF4's interaction with the growth factor GM-CSF.^[4] IRF4 expression is necessary for ensuring that monocyte-derived dendritic cells (Mo-DCs) can cross-present antigen to CD8+ cells.^[4]

IRF4 and IRF8 are also significant transcription factors in the differentiation of common myeloid progenitors (CMPs) into macrophages.^[4] IRF4 is expressed at a lower level than IRF8 in these progenitor cells; however, IRF4 expression appears to be particularly important for the development of M2 macrophages.^[4] JMJD3, which regulates IRF4, has been identified as an important regulator of M2 macrophage polarization, suggesting that IRF4 may also take part in this regulatory process.^[4]

In melanocytic cells the IRF4 gene may be regulated by MITF.^[8] IRF4 is a transcription factor that has been implicated in acute leukemia.^[9] This gene is strongly associated with pigmentation: sensitivity of skin to sun exposure, freckles, blue eyes, and brown hair color.^[10] A variant has been implicated in greying of hair.^[11]

The World Health Organization (2016) provisionally defined "large B-cell lymphoma with IRF4 rearrangement" as a rare indolent large B-cell lymphoma of children and adolescents. This indolent lymphoma mimics, and must be distinguished from, pediatric-type follicular lymphoma.^[12] The hallmark of large B-cell lymphoma with IRF4 rearrangement is the overexpression of the IRF4 gene by the disease's malignant cells. This overexpression is forced by the acquisition in these cells of a translocation of IRF4 from its site on the short (i.e. p) arm of chromosome 6 at position 25.3^[13] to a site near the IGH@ immunoglobulin heavy locus on the long (i.e. q) arm of chromosome 14 at position 32.33^[14][15]

IRF4 has been shown to interact with:

• Aiolos,^[5]
• BATF3,^[4]
• Blimp-1,^[4][7]
• BCL6,^[16]
• CD40,^[4][5]
• GM-CSF,^[4]
• IL-4,^[4][5]
• Ikaros,^[5]
• IRF8,^[4][5]
• JMJD3,^[4]
• MMP12,^[4]
• NFATC2,^[17]
• SPI1,^[18][19] and
• STAT6.^[16]

• Interferon regulatory factors

• FactorBook IRF4
• IRF4+protein,+human at the U.S. National Library of Medicine Medical Subject Headings (MeSH)

This article incorporates text from the United States National Library of Medicine, which is in the public domain.