NF-κB

You don't need to be Editor-In-Chief to add or edit content to WikiDoc. You can begin to add to or edit text on this WikiDoc page by clicking on the edit button at the top of this page. Next enter or edit the information that you would like to appear here. Once you are done editing, scroll down and click the Save page button at the bottom of the page.

Jump to: navigation, search
Image:NFKB mechanism of action.png
Mechanism of NF-κB action. In this figure, the NF-κB heterodimer between Rel and p50 proteins is used as an example. While in an inactivated state, NF-κB is located in the cytosol complexed with the inhibitory protein IκBα. Through the intermediacy of integral membrane receptors, a variety of extracellular signals can activate the enzyme IκB kinase (IKK). IKK in turn phosphorylates the IκBα protein which results in ubiquitination, dissociation of IκBα from NF-κB, and eventual degradation of IκBα by the proteosome. The activated NF-κB is then translocated into the nucleus where it binds to specific sequences of DNA called response elements (RE). the DNA/NF-κB complex then recruits other proteins such a coactivators and RNA polymerase which transcribe downstream DNA into mRNA which in turn is translated into protein which results in a change of cell function.
Image:NFKB structure schematic.png
Schematic diagram of NF-κB protein structure. There are two structural classes of NF-κB proteins: class I (top) and class II (bottom). Both classes of proteins contain a N-terminal DNA-binding domain (DBD) which also servers as a dimerization interface to other NF-κB transcription factors and in addition binds to the inhibitory IκBα protein. The C-terminus of class I proteins contains a number of ankyrin repeats and has transrepression activity. In contrast the C-terminus of class II proteins has a transactivation function.[1]
Image:1SVC.png
Top view of the crystallographic structure (PDB 1SVC) of a homodimer of the NFKB1 protein (green and magenta) bound to DNA (brown).
Identifiers
Symbol NFKB1
Entrez 4790
HUGO 7794
OMIM 164011
RefSeq NM_003998
UniProt P19838
Other data
Locus Chr. 4 q24
nuclear factor of kappa light polypeptide gene enhancer in B-cells 2 (p49/p100)
Identifiers
Symbol NFKB2
Entrez 4791
HUGO 7795
OMIM 164012
RefSeq NM_002502
UniProt Q00653
Other data
Locus Chr. 10 q24
Image:2RAM.png
Side view of the crystallographic structure (PDB 2RAM) of a homodimer of the RELA protein (green and magenta) bound to DNA (brown).
v-rel reticuloendotheliosis viral oncogene homolog A, nuclear factor of kappa light polypeptide gene enhancer in B-cells 3, p65 (avian)
Identifiers
Symbol RELA
Alt. Symbols NFKB3
Entrez 5970
HUGO 9955
OMIM 164014
RefSeq NM_021975
UniProt Q04206
Other data
Locus Chr. 11 q13
Identifiers
Symbol RELB
Entrez 5971
HUGO 9956
OMIM 604758
RefSeq NM_006509
UniProt Q01201
Other data
Locus Chr. 19 q13.2-19q13
Identifiers
Symbol REL
Entrez 5966
HUGO 9954
OMIM 164910
RefSeq NM_002908
UniProt Q04864
Other data
Locus Chr. 2 p13-p12

NF-κB (nuclear factor-kappa B) is a protein complex which is a transcription factor. NF-κB is found in almost all animal cell types and is involved in cellular responses to stimuli such as stress, cytokines, free radicals, ultraviolet irradiation, oxidized LDL, and bacterial or viral antigens.[1] NF-κB plays a key role in regulating the immune response to infection. Consistent with this role, incorrect regulation of NF-κB has been linked to cancer, inflammatory and autoimmune diseases, septic shock, viral infection and improper immune development. NF-κB has also been implicated in processes of synaptic plasticity and memory.[1]

Discovery

NF-κB was first discovered in the lab of Nobel Prize laureate David Baltimore via its interaction with an 11-base pair sequence in the immunoglobulin light-chain enhancer in B cells.[1]

Members

NF-κB family members share structural homology with the retroviral oncoprotein v-Rel, resulting in their classification as NF-κB/Rel proteins.[1]

There are five proteins in the mammalian NF-κB family:

  • NF-κB1 (also called p50) - NFKB1
  • NF-κB2 (also called p52) - NFKB2
  • RelA (also named p65) - RELA
  • RelB - RELB
  • c-Rel REL

In addition, there are NF-κB proteins in lower organisms, such as the fruit fly Drosophila, sea urchins, sea anemones and sponges.

Structure

All proteins of the NF-κB family share a Rel homology domain in their N-terminal halves. A subfamily of NF-κB proteins, including RelA, RelB and c-Rel, have a transactivation domain in their C-termini. In contrast, the NF-κB1 and NF-κB2 proteins are synthesized as large precursors, p105 and p100, which undergo processing to generate the mature NF-κB subunits, p50 and p52, respectively. The processing of p105 and p100 is mediated by the ubiquitin/proteasome pathway and involves selective degradation of their C-terminal region containing ankyrin repeats. While the generation of p52 from p100 is a tightly regulated process, p50 is produced from constitutive processing of p105.[1][1]

Activation of NF-κB

Part of NF-κB's importance in regulating cellular responses is that it belongs to the category of "rapid-acting" primary transcription factors---i.e., transcription factors which are present in cells in an inactive state and do not require new protein synthesis to be activated (other members of this family include transcription factors such as c-Jun, STATs and nuclear hormone receptors). This allows NF-κB to act as a "first responder" to harmful cellular stimuli. Stimulation of a wide variety of cell-surface receptors, such as[1] RANK, TNFR, IL1R leads directly to NF-κB activation and fairly rapid changes in gene expression.

Many bacterial products can activate NF-κB. The identification of Toll-like receptors (TLRs) as specific pattern recognition molecules and the finding that stimulation of TLRs leads to activation of NF-κB improved our understanding of how different pathogens activate NF-κB. For example, studies have identified TLR4 as the receptor for the LPS component of Gram-Negative bacteria. TLRs are key regulators of both innate and adaptive immune responses.

Unlike RelA, RelB, and c-Rel, the p50 and p52 NF-κB subunits do not contain transactivation domains in their C terminal halves. Nevertheless, the p50 and p52 NF-κB members play critical roles in modulating the specificity of NF-κB function. Although homodimers of p50 and p52 are generally repressors of κB site transcription, both p50 and p52 participate in target gene transactivation by forming heterodimers with RelA, RelB or c-Rel.[1] Additionally, p50 and p52 homodimers also bind to the nuclear protein Bcl-3, and such complexes can function as transcriptional activators.[1][1][1]

Inhibitors of NF-κB

In unstimulated cells, the NF-κB dimers are sequestered in the cytoplasm by a family of inhibitors, called IκBs (Inhibitor of kappa B), which are proteins that contain multiple copies of a sequence called ankyrin repeats. By virtue of their ankyrin repeat domains, the IκB proteins mask the nuclear localization signals (NLS) of NF-κB proteins and keep them sequestered in an inactive state in the cytoplasm.[1]

IκBs are a family of related proteins that have an N-terminal regulatory domain, followed by six or more ankyrin repeats and a PEST domain near their C terminus. Although the IκB family consists of IκBα, IκBβ, IκBγ, IκBε and Bcl-3, the best studied and major IκB protein is IκBα. Due to the presence of ankyrin repeats in their C-terminal halves, p105 and p100 also function as IκB proteins. Of all the IκB members, IκBγ is unique in that it is synthesized from the nf-kb1 gene using an internal promoter, thereby resulting in a protein which is identical to the C-terminal half of p105.[1]

Activation of the NF-κB is initiated by the signal-induced degradation of IκB proteins. This occurs primarily via activation of a kinase called the IκB kinase (IKK). IKK is composed of a heterodimer of the catalytic IKK alpha and IKK beta subunits and a "master" regulatory protein termed NEMO (NF-kappa B essential modulator) or IKK gamma. When activated by signals, usually coming from the outside of the cell, the IκB kinase phosphorylates two serine residues located in an IκB regulatory domain. When phosphorylated on these serines (e.g., serines 32 and 36 in human IκBα), the IκB inhibitor molecules are modified by a process called ubiquitination which then leads them to be degraded by a cell structure called the proteasome.

With the degradation of the IκB inhibitor, the NF-κB complex is then freed to enter the nucleus where it can 'turn on' the expression of specific genes that have DNA-binding sites for NF-κB nearby. The activation of these genes by NF-κB then leads to the given physiological response, for example, an inflammatory or immune response, a cell survival response, or cellular proliferation. NF-κB turns on expression of its own repressor, IκBα. The newly-synthesized IκBα then re-inhibits NF-κB and thus forms an auto feedback loop, that results in oscillating levels of NF-κB activity.[1] In addition, several viruses, including the AIDS virus HIV, have binding sites for NF-κB that controls the expression of viral genes, which in turn contribute to viral replication or viral pathogenicity. In the case of HIV-1, activation of NF-κB may, at least in part, be involved in activation of the virus from a latent, inactive state. YopJ is a factor secreted by Yersinia pestis, the causative agent of plague, that prevents the ubiquitination of IκB. This causes this pathogen to effectively inhibit the NF-κB pathway and thus block the immune response of a human infected with Yersinia.

NF-κB's role in cancer and other diseases

NF-κB is widely used by eukaryotic cells as a regulator of genes that control cell proliferation and cell survival. As such, many different types of human tumors have misregulated NF-κB: that is, NF-κB is constitutively active. Active NF-κB turns on the expression of genes that keep the cell proliferating and protect the cell from conditions that would otherwise cause it to die. In tumor cells, NF-κB is active either due to mutations in genes encoding the NF-κB transcription factors themselves or in genes that control NF-κB activity (such as IκB genes); in addition, some tumor cells secrete factors that cause NF-κB to become active. Blocking NF-κB can cause tumor cells to stop proliferating, to die, or to become more sensitive to the action of anti-tumor agents. Thus, NF-κB is the subject of much active research among pharmaceutical companies as a target for anti-cancer therapy.[1]

Because NF-κB controls many genes involved in inflammation, it is not surprising that NF-κB is found to be chronically active in many inflammatory diseases, such as inflammatory bowel disease, arthritis, sepsis, asthma among others. Many natural products (including anti-oxidants) that have been promoted to have anti-cancer and anti-inflammatory activity have also been shown to inhibit NF-κB. There is a controversial US patent (US patent 6,410,516)[1] that applies to the discovery and use of agents that can block NF-κB for therapeutic purposes. This patent is involved in several lawsuits, including Ariad v. Lilly. Recent work by Karin, Ben-Neriah and others has highlighted the importance of the connection between NF-κB, inflammation and cancer and underscored the value of therapies that regulate the activity of NF-κB.

Signaling in immunity

NF-kB is a major transcription factor which regulates genes responsible for both the innate immune response and the adaptive immune response. Upon activation of either the T- or B-cell receptor, NF-kB becomes activated through distinct signaling components. Upon ligation of the T-cell receptor, an adaptor molecule, ZAP70 is recruited via its SH2 domain to the cytoplasmic side of the receptor. ZAP70 helps recruit both LCK and PLCgamma, which causes activation of PKC. Through a cascade of phosphorylation events, the kinase complex is activated and NF-kB is able to enter the nucleus to upregulate genes involved in T-cell development, maturation and proliferation.

Conserved in evolution

NF-kB is found in a number of simple animals as well. These include Cnidarians (such as sea anemones and coral), Porifera (sponges) and insects (such as moths, mosquitoes and fruitflies). The sequencing of the genomes of Aedes aegypti, anopheles gambae, and the fruitfly Drosophila melanogaster has allowed comparative genetic and evolutionary studies on NF-kB. In those insect species, activation of NF-kB is triggered by the Toll pathway (which evolved independently in insects and mammals) and by the Imd pathway.[1]

See also

References

External links

v  d  e
Transcription factors and intracellular receptors
(1) Basic domains
(1.1) Basic leucine zipper (bZIP) Activating transcription factor (1, 2, 3, 4, 5, 6) • AP-1 (c-Fos, FOSB, FOSL1, FOSL2, c-Jun, JUNB, JUND) • BACH (1, 2) • C/EBP (α, β, γ, δ, ε, ζ) • CREB (1, 3) • GABPA • MAF (B, F, G, K) • NRL • NRF1 • XBP1
(1.2) Basic helix-loop-helix (bHLH) ATOH1 • AhR • AHRR • ARNT • ASCL1 • BMAL (ARNTL, ARNTL2) • CLOCK • HIF (1A, 3A) • Myogenic regulatory factors (MyoD, Myogenin, MYF5, MYF6) • NEUROD1 • Twist • USF1
(1.3) bHLH-ZIP Myc • MITF • SREBP (1, 2)
(1.6) Basic helix-span-helix (bHSH) AP-2
(2) Zinc finger
DNA-binding domains
(2.1) Nuclear receptor (Cys4) subfamily 1 (Thyroid hormone (α, β), CAR, FXR, LXR (α, β), PPAR (α, β/δ, γ), PXR, RAR (α, β, γ), ROR (α, β, γ), Rev-ErbA (α, β), VDR) • subfamily 2 (COUP-TF (I, II), Ear-2, HNF4 (α, γ), PNR, RXR (α, β, γ), Testicular receptor (2, 4), TLX) • subfamily 3 (Steroid hormone (Estrogen (α, β), Estrogen related (α, β, γ), Androgen, Glucocorticoid, Mineralocorticoid, Progesterone)) • subfamily 4 NUR (NGFIB, NOR1, NURR1) • subfamily 5 (LRH-1, SF1) • subfamily 6 (GCNF) • subfamily 0 (DAX1, SHP)
(2.2) Other Cys4 GATA (1, 2, 3, 4, 5, 6)
(2.3) Cys2His2 General transcription factors (TFIIA, TFIIB, TFIID, TFIIE, TFIIF, TFIIH: 1, 2) • GLI-Krüppel family (1, 2, 3, YY1) • KLF (2, 4, 5, 6, 10, 11, 12, 13) • Sp1 • zinc finger (3, 35, 43, 146, 148, 165, 217, 268, 281, 350) • Zbtb7 (7A) • ZBT (16, 17, 33)
(2.4) Cys6 HIVEP1
(3) Helix-turn-helix
domains
(3.1) Homeo domain ARX • Homeobox (A1, A3, A4, A5, A7, A9, A10, A11, A13, B1, B2, B3, B4, B5, B6, B7, B8, B9, B13, C4, C6, C8, C9, C13, D1, D3, D4, D9, D10, D11, D12, D13) • NANOG • NKX (2-1, 2-5, 3-1) • POU domain (PIT-1, BRN-3: 1, 2, Octamer transcription factor: 1, 2, 3/4, 6, 7)
(3.2) Paired box PAX (1, 2, 3, 4, 5, 6, 7, 8, 9)
(3.3) Fork head / winged helix E2F (1, 2, 3, 4, 5) • FOX proteins (C1, C2, E1, G1, H1, L2, M1, N3, O3, O4, P1, P2, P3)
(3.4) Heat Shock Factors HSF1
(3.5) Tryptophan clusters ELF (4, 5) • Interferon regulatory factors (1, 2, 3, 4, 5, 6, 7, 8) • MYB
(3.6) TEA domain transcriptional enhancer factor 1, 2
(4) β-Scaffold factors with
minor groove contacts
(4.1) Rel homology region NF-κB (NFKB1, NFKB2, REL, RELA, RELB) • NFAT (5, C1, C2, C3, C4)
(4.2) STAT STAT (1, 2, 3, 4, 5, 6)
(4.3) p53 p53
(4.4) MADS box Mef2 (A, B, C, D) • SRF
(4.7) High mobility group HNF (1A, 1B) • LEF1 • SOX (3, 4, 6, 9, 10, 13, 18) • SRY • SSRP1
(4.10) Cold-shock domain CSDA
(0) Other
transcription factors
(0.2) HMGI(Y) HMGA (1, 2)
(0.3) Pocket domain Rb • RBL1 • RBL2
(0.6) Miscellaneous ARID (1A, 1B, 2, 3A, 3B, 4A) • CAP • Rho/Sigma • R-SMAD
de:NF-κB

fr:NF-kB it:NF-kB vi:NF-kB


Acknowledgement and Attribution Regarding Sources of Content

Some of the initial content on this page may be incorporated in part from copyleft sources in the public domain including wikis such as Wikipedia and AskDrWiki. Drug information for patients came from the The National Library of Medicine. Infectious disease information may have come from the Centers for Disease Control (CDC). Differential Diagnoses are drawn from clinicians as well as an amalgamation of 3 sources: 1.The Disease Database; 2. Kahan, Scott, Smith, Ellen G. In A Page: Signs and Symptoms. Malden, Massachusetts: Blackwell Publishing, 2004:3; 3. Sailer, Christian, Wasner, Susanne. Differential Diagnosis Pocket. Hermosa Beach, CA: Borm Bruckmeir Publishing LLC, 2002:7 .

Retrieved from "http://en.wikidoc.org/index.php/NF-%CE%BAB"
Personal tools
related articles
often viewed next [ + ]