EIF2AK1
Description
The EIF2AK1 (eukaryotic translation initiation factor 2 alpha kinase 1) is a protein-coding gene located on chromosome 7.
Eukaryotic translation initiation factor 2-alpha kinase 1 is an enzyme that in humans is encoded by the EIF2AK1 gene.
== Function == EIF2AK1 inhibits protein synthesis at the translation initiation level, in response to various stress conditions, including oxidative stress, heme deficiency, osmotic shock and heat shock. EIF2AK1 exerts its function through the phosphorylation of EIF2S1 at 'Ser-48' and 'Ser-51', thus preventing its recycling. Binds hemin forming a 1:1 complex through a cysteine thiolate and histidine nitrogenous coordination. This binding occurs with moderate affinity, allowing it to sense the heme concentration within the cell. Owing to this unique heme-sensing capacity, it plays a crucial role in shutting off protein synthesis during acute heme-deficient conditions. In red blood cells (RBCs), it controls hemoglobin synthesis ensuring a coordinated regulation of the synthesis of the heme and globin moieties of hemoglobin. Thus plays an essential protective role for RBC survival in anemias of iron deficiency. EIF2AK1 also act to moderate ER stress during acute heme-deficient conditions.
== Enzymology == EIF2AK1 is a kinase, thus it catalyses the following reaction: ATP + a protein = ADP + a phosphoprotein EIF2AK1 is induced by acute heme depletion, that not only increases EIF2AK1 protein levels, but also stimulates kinase activity by autophosphorylation.
EIF2AK1 is a metabolic-stress sensing protein kinase that phosphorylates the alpha subunit of eukaryotic translation initiation factor 2 (EIF2S1/eIF-2-alpha) in response to various stress conditions, including heme deficiency, oxidative stress, osmotic shock, mitochondrial dysfunction and heat shock. It acts as a key activator of the integrated stress response (ISR) required for adaptation to these stresses. EIF2S1/eIF-2-alpha phosphorylation converts EIF2S1/eIF-2-alpha into a global protein synthesis inhibitor, leading to a global attenuation of cap-dependent translation, while concomitantly initiating the preferential translation of ISR-specific mRNAs, such as the transcriptional activator ATF4, and hence allowing ATF4-mediated reprogramming. EIF2AK1 acts as a key sensor of heme-deficiency: in normal conditions, it binds hemin via a cysteine thiolate and histidine nitrogenous coordination, leading to inhibit the protein kinase activity. This binding occurs with moderate affinity, allowing it to sense the heme concentration within the cell: heme depletion relieves inhibition and stimulates kinase activity, activating the ISR. Thanks to this unique heme-sensing capacity, EIF2AK1 plays a crucial role to shut off protein synthesis during acute heme-deficient conditions. In red blood cells (RBCs), EIF2AK1 controls hemoglobin synthesis ensuring a coordinated regulation of the synthesis of its heme and globin moieties. It thereby plays an essential protective role for RBC survival in anemias of iron deficiency. Iron deficiency also triggers activation by full-length DELE1. EIF2AK1 also activates the ISR in response to mitochondrial dysfunction: HRI/EIF2AK1 protein kinase activity is activated upon binding to the processed form of DELE1 (S-DELE1), thereby promoting the ATF4-mediated reprogramming.
EIF2AK1 is also known as HCR, HRI, LEMSPAD, hHRI.