Response of EIF2AK1 (HRI) to heme deficiency (Homo sapiens)

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4, 11, 12, 14-16, 19...1, 183810, 338, 9, 30, 4323, 397, 28, 39, 41, 45534, 37, 44146, 1353, 7, 21, 22, 453, 21nucleoplasmcytosolCEBPG p-T,T486,T488-EIF2AK1:ferriheme dimerCEBPB ATPGRB10 geneCEBPB,CEBPG,DDIT3ATF4 EIF2S3 PPP1R15Ap-T-EIF2AK1 ATF4 mRNAp-S52-EIF2S1 PPP1R15A gene ATF3:ATF4:CEBPB:CHAC1 geneATF4 EIF2S2 EIF2S3 CEBPG CEBPG CHAC1 gene DDIT3 geneCEBPB FeHM TRIB3DDIT3 mRNAATF4:PPP1R15A geneATF4ATF4 PPP1R15A geneCEBPBATF3p-T-EIF2AK1:2xferriheme dimerASNSDDIT3 gene ATF4:CEBPB,CEBPG:ASNS geneDDIT3 CHAC1 gene ATF3 CHAC1 genePPP1R15A mRNATRIB3:CHAC1 geneCEBPB,CEBPGATF5ATF5 geneCEBPB FeHM ATPDDIT3 ATF4:DDIT3 geneDDIT3 CEBPG p-S52-EIF2S1:EIF2S2:EIF2S3CEBPG FeHM CEBPB ATF5-201 mRNADDIT3ADPp-T-EIF2AK1:ferriheme dimerATF4 GRB10TRIB3 geneATF4:CEBPB,CEBPG,DDIT3:TRIB3 geneADPTRIB3 gene CHAC1EIF2S1:EIF2S2:EIF2S3ATF4 EIF2S2 ATF4 CEBPB FeHMEIF2S1 ATF4:CEBPB,CEBPG,DDIT3:ATF5 genep-T-EIF2AK1 p-T,T486,T488-EIF2AK1 ATF5 gene ASNS gene TRIB3 CEBPB ASNS gene2, 36, 402, 36, 405253, 17, 21


Description

The kinases of the integrated stress response phosphorylate EIF2S1 (eIF2-alpha) to regulate cellular translation. The kinases comprise PERK (also called EIF2AK3), which responds to unfolded protein in the endoplasmic reticulum; EIF2AK2 (also called PKR), which responds to cytosolic double-stranded RNA; EIF2AK4 (also called GCN2), which responds to amino acid deficiency; and EIF2AK1 (also called heme-regulated inhibitor, HRI, and heme-controlled repressor, HCR), which responds to heme deficiency and cytosolic unfolded protein. Each molecule of EIF2AK1 binds two molecules of heme, one bound near the N-terminus and one bound at the kinase insert (KI) domain that inhibits the kinase activity of EIF2AK1 (inferred from the rabbit homolog in Chefalo et al. 1998, Rafie-Kolpin et al. 2000, inferred from the mouse homolog in Misanova et al. 2006, Hirai et al. 2007, Igarashi et al. 2008). Dissociation of heme from the KI domain activates the kinase activity of EIF2AK1, which autophosphorylates (inferred from the mouse homolog in Bauer et al. 2001, Rafie-Kolpin et al. 2003, Igarashi et al. 2011) and then phosphorylates EIF2S1 (Bhavnani et al. 2018, inferred from the rabbit homologs in Chefalo et al. 1998, Rafie-Kolpin et al. 2000, inferred from the mouse homologs in Lu et al. 2001, Rafie-Kolpin et al. 2003, Igarashi et al. 2011).
Phosphorylated EIFS1 causes a reduction in general cellular translation and thereby coordinates globin synthesis with heme availability during erythropoiesis (inferred from mouse knockout in Han et al. 2001, reviewed in Chen et al. 2014). Translation of mitochondrial and cytosolic ribosomal proteins is most severely reduced, causing a decrease in cellular protein synthesis (inferred from mouse homologs in Zhang et al. 2019). Lack of EIF2AK1 causes accumulation of unfolded globins devoid of heme and consequent anemia in iron-deficient mice (inferred from mouse knockout in Han et al. 2001). Activation of the cytoplasmic unfolded protein response and impaired mitochondrial respiration are also observed in HRI deficiency (inferred from mouse homologs in Zhang et al. 2019).
Phosphorylation of EIFS1 activates translation of certain mRNAs such as ATF4, ATF5, and DDIT3 (CHOP) that have upstream ORFs (inferred from mouse homologs in Harding et al. 2000). ATF4 in turn activates programs of gene expression that ameliorate effects of the stress to maintain mitochondrial function, redox homeostasis, and erythroid differentiation (inferred from mouse homologs in Zhang et al. 2019). Unresolved stress, however, can eventually lead to apoptosis regulated by DDIT3. EIF2AK1 also represses mTORC1 (mechanistic target of mechanistic target of rapamycin complex 1) signaling via ATF4-mediated induction of GRB10 as a feedback mechanism to attenuate erythropoietin-mTORC1-stimulated ineffective erythropoiesis in iron deficiency anemia (inferred from mouse homologs in Zhang et al. 2018 and Zhang et. al. 2019).
EIF2AK1 is also activated by heat shock, arsenite (oxidative stress), and osmotic stress (inferred from mouse homologs in Lu et al. 2001). The mechanisms by which these stresses act on EIF2AK1 are independent of heme but are not yet fully elucidated. Furthermore, EIF2AK1 is involved in the production of human fetal hemoglobin, and EIF2AK1-mediated stress response has emerged as a potential therapeutic target for hemoglobinopathies (reviewed in Chen and Zhang 2019).
In addition to regulation of erythropoiesis, EIF2AK1 shows effects outside of the erythroid lineage, including requirement for the maturation and functions of macrophages (inferred from mouse homologs in Liu et al. 2007), reduction in endoplasmic reticulum stress in hepatocytes, activation of hepatic expression of fibroblast growth factor, and mediation of translation of GRIN2B (GluN2B. a subunit of the NMDA receptor) and BACE1 in the nervous system (reviewed in Burwick and Aktas 2017). HRI-integrated stress response is activated in human cancer cell lines and primary multiple myeloma cells, and has emerged as a molecular target of anticancer agents (reviewed in Burwick and Aktas 2017; reviewed in Chen and Zhang 2019). View original pathway at Reactome.

Comments

Reactome-Converter 
Pathway is converted from Reactome ID: 9648895
Reactome-version 
Reactome version: 75
Reactome Author 
Reactome Author: May, Bruce

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Bibliography

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History

CompareRevisionActionTimeUserComment
114735view16:22, 25 January 2021ReactomeTeamReactome version 75
113179view11:24, 2 November 2020ReactomeTeamReactome version 74
112789view17:47, 9 October 2020DeSlOntology Term : 'stress response pathway' added !
112744view16:14, 9 October 2020ReactomeTeamNew pathway

External references

DataNodes

View all...
NameTypeDatabase referenceComment
ADPMetaboliteCHEBI:456216 (ChEBI)
ASNS gene ProteinENSG00000070669 (Ensembl)
ASNS geneGeneProductENSG00000070669 (Ensembl)
ASNSProteinP08243 (Uniprot-TrEMBL)
ATF3 ProteinP18847 (Uniprot-TrEMBL)
ATF3:ATF4:CEBPB:CHAC1 geneComplexR-HSA-9653892 (Reactome)
ATF3ProteinP18847 (Uniprot-TrEMBL)
ATF4 ProteinP18848 (Uniprot-TrEMBL)
ATF4 mRNARnaENST00000404241 (Ensembl)
ATF4:CEBPB,CEBPG,DDIT3:ATF5 geneComplexR-HSA-9653740 (Reactome)
ATF4:CEBPB,CEBPG,DDIT3:TRIB3 geneComplexR-HSA-9635876 (Reactome)
ATF4:CEBPB,CEBPG:ASNS geneComplexR-HSA-9635898 (Reactome)
ATF4:DDIT3 geneComplexR-HSA-9655080 (Reactome)
ATF4:PPP1R15A geneComplexR-HSA-9654773 (Reactome)
ATF4ProteinP18848 (Uniprot-TrEMBL)
ATF5 gene ProteinENSG00000169136 (Ensembl)
ATF5 geneGeneProductENSG00000169136 (Ensembl)
ATF5-201 mRNARnaENST00000423777 (Ensembl)
ATF5ProteinQ9Y2D1 (Uniprot-TrEMBL)
ATPMetaboliteCHEBI:30616 (ChEBI)
CEBPB ProteinP17676 (Uniprot-TrEMBL)
CEBPB,CEBPG,DDIT3ComplexR-HSA-9654226 (Reactome)
CEBPB,CEBPGComplexR-HSA-9658331 (Reactome)
CEBPBProteinP17676 (Uniprot-TrEMBL)
CEBPG ProteinP53567 (Uniprot-TrEMBL)
CHAC1 gene ProteinENSG00000128965 (Ensembl)
CHAC1 geneGeneProductENSG00000128965 (Ensembl)
CHAC1ProteinQ9BUX1 (Uniprot-TrEMBL)
DDIT3 ProteinP35638 (Uniprot-TrEMBL)
DDIT3 gene ProteinENSG00000175197 (Ensembl)
DDIT3 geneGeneProductENSG00000175197 (Ensembl)
DDIT3 mRNARnaENST00000346473 (Ensembl)
DDIT3ProteinP35638 (Uniprot-TrEMBL)
EIF2S1 ProteinP05198 (Uniprot-TrEMBL)
EIF2S1:EIF2S2:EIF2S3ComplexR-HSA-72515 (Reactome)
EIF2S2 ProteinP20042 (Uniprot-TrEMBL)
EIF2S3 ProteinP41091 (Uniprot-TrEMBL)
FeHM MetaboliteCHEBI:36144 (ChEBI)
FeHMMetaboliteCHEBI:36144 (ChEBI)
GRB10 geneGeneProductENSG00000106070 (Ensembl)
GRB10ProteinQ13322 (Uniprot-TrEMBL)
PPP1R15A gene ProteinENSG00000087074 (Ensembl)
PPP1R15A geneGeneProductENSG00000087074 (Ensembl)
PPP1R15A mRNARnaENST00000200453 (Ensembl)
PPP1R15AProteinO75807 (Uniprot-TrEMBL)
TRIB3 ProteinQ96RU7 (Uniprot-TrEMBL)
TRIB3 gene ProteinENSG00000101255 (Ensembl)
TRIB3 geneGeneProductENSG00000101255 (Ensembl)
TRIB3:CHAC1 geneComplexR-HSA-9654227 (Reactome)
TRIB3ProteinQ96RU7 (Uniprot-TrEMBL)
p-S52-EIF2S1 ProteinP05198 (Uniprot-TrEMBL)
p-S52-EIF2S1:EIF2S2:EIF2S3ComplexR-HSA-9633006 (Reactome)
p-T,T486,T488-EIF2AK1 ProteinQ9BQI3 (Uniprot-TrEMBL)
p-T,T486,T488-EIF2AK1:ferriheme dimerComplexR-HSA-9648885 (Reactome)
p-T-EIF2AK1 ProteinQ9BQI3 (Uniprot-TrEMBL)
p-T-EIF2AK1:2xferriheme dimerComplexR-HSA-9648886 (Reactome)
p-T-EIF2AK1:ferriheme dimerComplexR-HSA-9648893 (Reactome)

Annotated Interactions

View all...
SourceTargetTypeDatabase referenceComment
ADPArrowR-HSA-9648883 (Reactome)
ADPArrowR-HSA-9648888 (Reactome)
ASNS geneR-HSA-1791118 (Reactome)
ASNS geneR-HSA-9635915 (Reactome)
ASNSArrowR-HSA-1791118 (Reactome)
ATF3:ATF4:CEBPB:CHAC1 geneArrowR-HSA-9653893 (Reactome)
ATF3:ATF4:CEBPB:CHAC1 geneArrowR-HSA-9653894 (Reactome)
ATF3R-HSA-9653893 (Reactome)
ATF4 mRNAR-HSA-381128 (Reactome)
ATF4:CEBPB,CEBPG,DDIT3:ATF5 geneArrowR-HSA-9653724 (Reactome)
ATF4:CEBPB,CEBPG,DDIT3:ATF5 geneArrowR-HSA-9653742 (Reactome)
ATF4:CEBPB,CEBPG,DDIT3:TRIB3 geneArrowR-HSA-9635912 (Reactome)
ATF4:CEBPB,CEBPG,DDIT3:TRIB3 geneArrowR-HSA-9635927 (Reactome)
ATF4:CEBPB,CEBPG:ASNS geneArrowR-HSA-1791118 (Reactome)
ATF4:CEBPB,CEBPG:ASNS geneArrowR-HSA-9635915 (Reactome)
ATF4:DDIT3 geneArrowR-HSA-9655071 (Reactome)
ATF4:DDIT3 geneArrowR-HSA-9655086 (Reactome)
ATF4:PPP1R15A geneArrowR-HSA-9654752 (Reactome)
ATF4:PPP1R15A geneArrowR-HSA-9654774 (Reactome)
ATF4ArrowR-HSA-381128 (Reactome)
ATF4ArrowR-HSA-9654792 (Reactome)
ATF4R-HSA-9635915 (Reactome)
ATF4R-HSA-9635927 (Reactome)
ATF4R-HSA-9653742 (Reactome)
ATF4R-HSA-9653893 (Reactome)
ATF4R-HSA-9654752 (Reactome)
ATF4R-HSA-9655086 (Reactome)
ATF5 geneR-HSA-9653724 (Reactome)
ATF5 geneR-HSA-9653742 (Reactome)
ATF5-201 mRNAArrowR-HSA-9653724 (Reactome)
ATF5-201 mRNAR-HSA-9653745 (Reactome)
ATF5ArrowR-HSA-9653745 (Reactome)
ATPR-HSA-9648883 (Reactome)
ATPR-HSA-9648888 (Reactome)
CEBPB,CEBPG,DDIT3R-HSA-9635927 (Reactome)
CEBPB,CEBPG,DDIT3R-HSA-9653742 (Reactome)
CEBPB,CEBPGR-HSA-9635915 (Reactome)
CEBPBR-HSA-9653893 (Reactome)
CHAC1 geneR-HSA-9653893 (Reactome)
CHAC1 geneR-HSA-9653894 (Reactome)
CHAC1ArrowR-HSA-9653894 (Reactome)
DDIT3 geneR-HSA-9655071 (Reactome)
DDIT3 geneR-HSA-9655086 (Reactome)
DDIT3 mRNAArrowR-HSA-9655071 (Reactome)
DDIT3 mRNAR-HSA-9650722 (Reactome)
DDIT3ArrowR-HSA-9650722 (Reactome)
EIF2S1:EIF2S2:EIF2S3R-HSA-9648888 (Reactome)
FeHMArrowR-HSA-9648880 (Reactome)
GRB10 geneR-HSA-9654792 (Reactome)
GRB10ArrowR-HSA-9654792 (Reactome)
PPP1R15A geneR-HSA-9654752 (Reactome)
PPP1R15A geneR-HSA-9654774 (Reactome)
PPP1R15A mRNAArrowR-HSA-9654774 (Reactome)
PPP1R15A mRNAR-HSA-9650710 (Reactome)
PPP1R15AArrowR-HSA-9650710 (Reactome)
R-HSA-1791118 (Reactome) The Asparagine Synthetase (ASNS) gene is transcribed to yield mRNA and the mRNA is translated to yield protein (Chen et al. 2004, Lee et al. 2008, Gjymishka et al. 2009, Sikalidis et al. 2011, Balasubramanian et al. 2013, inferred from the mouse homolog). Transcription of ASNS is activated by the unfolded protein response (Gjymishka et al. 2009), amino acid deficiency (Chen et al. 2004, Lee et al. 2008, Sikalidis et al. 2011, Balasubramanian et al. 2013, inferred from the mouse homolog), and heme deficiency (inferred from the mouse homolog).
R-HSA-381128 (Reactome) ATF4 mRNA is translated to yield ATF4 protein, which then transits to the nucleus (Blais et al. 2004, Ross et al. 2018). The mRNA of ATF4 contains 2 upstream ORFs (uORFs) (Ross et al. 2018 and inferred from the mouse homolog). The second uORF overlaps the ORF encoding ATF4 and thus prevents translation of ATF4. When EIF2S1 (eIF2-alpha) is phosphorylated, translation initiation is decreased overall, translation of the uORFs is suppressed, and translation of the ORF encoding ATF4 is increased (Blais et al. 2004, Ross et al. 2018, and inferred from mouse homologs).
R-HSA-9635912 (Reactome) The TRIB3 (TRB3, NIPK) gene is transcribed to yield mRNA and the mRNA is translated to yield TRIB3 protein (Ohoka et al. 2005, Ord and Ord 2005, Lee et al. 2008, Sikalidis et al. 2011, Ord et al. 2016, and inferred from the mouse homolog). Transcription of TRIB3 is enhanced in response to amino acid deficiency (Lee et al. 2008, Sikalidis et al. 2011, and inferred from mouse homologs), endoplasmic reticulum stress (Ohoka et al. 2005, Ord and Ord 2005), oxidative stress (Ord and Ord 2005, Ord et al. 2016) and heme deficiency (inferred from mouse homologs). ATF4 bound with a CEBP family protein to the promoter of TRIB3 (NIPK, TRB3) enhances transcription of TRIB3 (Ohoka et al. 2005, Ord and Ord 2005, Lee et al. 2008, Sikalidis et al. 2011, Ord et al. 2016, and inferred from mouse homologs).
R-HSA-9635915 (Reactome) ATF4 and CEBPB or CEBPG bind a CEBP-ATF regulatory element (CARE) in the promoter of the ASNS gene (Siu et al 2001, Chen et al. 2004, inferred from mouse homologs). ATF4 binds rapidly during the first 2 hours after amino acid deprivation (Chen et al. 2004). ATF3 and CEBPB accumulate on the ASNS promoter more slowly and appear to correlate with decreasing transcription of ASNS (Chen et al. 2004). EIF2AK1 acts via ATF4 to activate transcription of ASNS in response to heme deficiency (inferred from mouse homologs).
R-HSA-9635927 (Reactome) ATF4 binds composite CEBP-ATF elements located in three 33-bp tandem repeats in the promoter of the TRIB3 (TRB3, NIPK) gene (Ohoka et al. 2005, Ord and Ord 2005). ATF4 cooperates with DDIT3 to activate TRIB3 promoter activity (Ohoka et al. 2005). ATF4 also appears to bind as a heterodimer with CEBPB or CEBPG, which is required for full response to amino acid deficiency (inferred from mouse homologs).
R-HSA-9648880 (Reactome) One molecule of hemin (ferriheme b chloride) tightly binds the N-terminal domain of EIF2AK1 (HRI) and one molecule of hemin loosely binds the kinase insert (KI) domain of EIF2AK1 (Bhavnani et al. 2018, and inferred from rabbit and mouse homologs). When cytosolic heme concentrations are low, heme dissociates from the KI domain, resulting in activation of the kinase activity of EIF2AK1 (inferred from rabbit and mouse homologs).
R-HSA-9648883 (Reactome) During heme deficiency, EIF2AK1 (HRI) autophosphorylates, notably on threonine residues in the activation loop (inferred from the mouse homolog). EIF2AK1 also has many phosphorylated residues prior to activation in response to heme deficiency (inferred from the mouse homolog). Autophosphorylation of threonine-488 (threonine-485 in the mouse homolog) is essential for kinase activity of EIF2AK1 acting on EIF2S1 (eIF2-alpha) in response to heme deficiency and oxidative stress by arsenite (inferred from the mouse homolog).
R-HSA-9648888 (Reactome) Phosphorylated EIF2AK1 phosphorylates EIF2S1 (eIF2-alpha) on serine-52 (homologous to serine-51 of the rabbit homologue) (inferred from rabbit and mouse homologs). Phosphothreonine 488 (homologous to phosphothreonine-485 of the mouse homolog) of EIF2AK1 is required for kinase activity of EIF2AK1 acting on EIF2S1 (inferred from mouse homologs). Phosphorylated EIF2S1 in the EIF2alpha complex causes the complex to bind more tightly to the GTP exchange factor EIF2B, which inhibits exchange of GDP for GTP, and hence inhibits recycling of EIF2alpha to the active (GTP-bound) state. The result is a general decrease of translation in the cell, with a few mRNAs, such as ATF4, that possess upstream ORFs exhibiting increased translation. The decrease in translation of globin mRNAs in particular helps to maintain a 1:1 balance of heme and globin in erythropoiesis during heme deficiency.
R-HSA-9650710 (Reactome) The PPP1R15A (GADD34) mRNA is translated to yield PPP1R15A protein which then associates with the cytosolic faces of the endoplasmic reticulum membrane and the mitochondrial outer membrane (inferred from the mouse homolog). The PPP1R15A mRNA contains 2 upstream ORFs (uORFs) that limit translation of the downstream PPP1R15A coding region (inferred from the mouse homolog). During certain stresses, EIF2S1 (eIF2-alpha) is phosphorylated, causing a reduction in initiation at the uORFs and increased translation of the PPP1R15A coding region (inferred from mouse homologs).
R-HSA-9650722 (Reactome) The DDIT3 mRNA is translated to yield DDIT3 (CHOP) protein (Jousse et al. 2001, and inferred from the mouse homolog), which is then imported into the nucleus. The mRNA of DDIT3 contains an upstream ORF (uORF) which has a start codon in an unfavorable context (Jousse et al. 2001, and inferred from the mouse homolog), resulting in low expression of the downstream DDIT3 coding region. When EIF2S1 (eIF2-alpha) is phosphorylated in response to stress, translation of the uORF is suppressed and translation of DDIT3 is increased (inferred from the mouse homolog).
R-HSA-9653724 (Reactome) The ATF5 gene is transcribed to yield mRNA (Watatani et al. 2007, Wei et al. 2010, and inferred from the mouse homolog). Transcription of ATF5 is activated by a heterodimer of ATF4 and a CEBP factor in response to proteasome inhibition, heme deficiency, endoplasmic reticulum stress, and amino acid deficiency (inferred from mouse homologs).
R-HSA-9653742 (Reactome) ATF4 and a member of the CEBP family of transcription factors (CEBPB, CEBPG, or DDIT3, also known as CHOP) bind as a heterodimer to a composite CEBP-ATF element in the promoter of the ATF5 gene (inferred from mouse homologs).
R-HSA-9653745 (Reactome) The ATF5 mRNA is translated to yield ATF5 protein (Watatani et al. 2008, and inferred from the mouse homolog) which is then imported into the nucleus. The ATF5 mRNA contains 2 upstream ORFs (uORFs) which inhibit translation of the downstream ATF5 coding region (Watatani et al. 2008). Translation of uORF2 also targets the mRNA for nonsense-mediated decay (Hatano et al. 2013). During stresses such as amino acid limitation and arsenite-induced oxidative stress, EIF2S1 (eIF2-alpha) is phosphorylated, decreasing translation initiation at the uORFs and increasing translation of ATF5 (Watatani et al. 2008, and inferred from the mouse homolog).
R-HSA-9653893 (Reactome) ATF4 binds the ATF/CRE element and the ACM elements in the promoter of the CHAC1 gene. ATF3 and CEBPB bind the ATF/CRE element (Crawford et al. 2015). The stoichiometry and interaction between the transcription factors at the promoter is unknown.
R-HSA-9653894 (Reactome) The CHAC1 gene is transcribed to yield mRNA and the mRNA is translated to yield CHAC1 protein (Crawford et al. 2015, and inferred from the mouse homolog). The transcription factors ATF4, ATF3, and CEBPB (full length) bind ATF/CRE and ACM elements in the CHAC1 promoter and activate transcription of CHAC1 in response to endoplasmic reticulum stress (Crawford et al. 2015). Expression of CHAC1 is also activated by heme deficiency (inferred from the mouse homolog). TRIB3 binds the CHAC1 promoter and represses transcription of CHAC1 which leads to decreased cell death during oxidative stress (inferred from mouse homologs).
R-HSA-9654752 (Reactome) ATF4 binds a conserved site in the promoter of the PPP1R15A (GADD34) gene in response to endoplasmic reticulum stress and traumatic brain injury (inferred from mouse homologs). ATF4 forms homodimers and heterodimers with other bZip proteins, however the binding partner of ATF4 at the PPP1R15A promoter is unknown. EIF2AK1 activates transcription of PPP1R15A via ATF4 in response to heme deficiency (inferred from mouse homologs).
R-HSA-9654774 (Reactome) The PPP1R15A (GADD34) gene is transcribed to yield mRNA (Hollander et al. 1997, Hollander et al. 2001, Oh-Hashi et al. 2001, and inferred from the mouse homolog). Transcription of PPP1R15A is activated by ATF4, which binds the PPP1R15A promoter in response to certain stresses such as endoplasmic reticulum stress, traumatic brain injury, and heme deficiency (inferred from mouse homologs).
R-HSA-9654792 (Reactome) The GRB10 gene is transcribed to yield mRNA and the mRNA is translated to yield GRB10 protein (inferred from the mouse homolog). Expression of GRB10 is activated by ATF4 in response to endoplasmic reticulum stress and heme deficiency (inferred from the mouse homolog).
R-HSA-9655071 (Reactome) The DDIT3 gene is transcribed to yield mRNA. Transcription of DDIT3 is activated by ATF4 in response to heme deficiency, which activates ATF4 expression via the integrated stress kinase EIF2AK1 (HRI) (inferred from the mouse, rat, and hamster homologs).
R-HSA-9655086 (Reactome) ATF4 binds a composite CEBP-ATF element in the promoter of the DDIT3 (CHOP, GADD153) gene in response to oxidative stress caused by arsenite (inferred from rat homologs) and amino acid deficiency (Bruhat et al. 2000, Averous et al. 2004, Bruhat et al. 2007, Cherasse et al. 2007). Both arsenite and heme deficiency regulate DDIT3 via EIF2AK1 (HRI) therefore heme deficiency is inferred to produce similar regulation of DDIT3 by ATF4. (Amino acid deficiency regulates DDIT3 via EIF2AK4.) The CEBP binding partner of ATF4 at the CEBP-ATF4 site is unknown. Phosphorylated ATF2 together with ATF4 activate DDIT3 in response to amino acid deficiency (Bruhat et al. 2000, Averous et al. 2004, Bruhat et al. 2007), however the role of ATF2 in heme deficiency is unknown.
TRIB3 geneR-HSA-9635912 (Reactome)
TRIB3 geneR-HSA-9635927 (Reactome)
TRIB3:CHAC1 geneTBarR-HSA-9653894 (Reactome)
TRIB3ArrowR-HSA-9635912 (Reactome)
p-S52-EIF2S1:EIF2S2:EIF2S3ArrowR-HSA-381128 (Reactome)
p-S52-EIF2S1:EIF2S2:EIF2S3ArrowR-HSA-9648888 (Reactome)
p-S52-EIF2S1:EIF2S2:EIF2S3ArrowR-HSA-9650710 (Reactome)
p-S52-EIF2S1:EIF2S2:EIF2S3ArrowR-HSA-9650722 (Reactome)
p-S52-EIF2S1:EIF2S2:EIF2S3ArrowR-HSA-9653745 (Reactome)
p-T,T486,T488-EIF2AK1:ferriheme dimerArrowR-HSA-9648883 (Reactome)
p-T,T486,T488-EIF2AK1:ferriheme dimermim-catalysisR-HSA-9648888 (Reactome)
p-T-EIF2AK1:2xferriheme dimerR-HSA-9648880 (Reactome)
p-T-EIF2AK1:ferriheme dimerArrowR-HSA-9648880 (Reactome)
p-T-EIF2AK1:ferriheme dimerR-HSA-9648883 (Reactome)
p-T-EIF2AK1:ferriheme dimermim-catalysisR-HSA-9648883 (Reactome)
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