Signaling by ERBB4 (Homo sapiens)

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11, 13, 14, 17, 19...3819, 538, 27, 8536, 46654519, 53, 705538452, 13, 3636, 40, 836514, 17, 22, 29, 42...818138381745818123, 6981268127, 8527, 8517, 5327, 85668126386513, 40, 83236538458138816936, 4619, 53, 6581mitochondrial matrixcytosolnucleoplasmUBC(305-380) ESR1 GABRA1 ERBB4jmAcyt1s80 ERBB4jmAcyt2s80 p-Y1172,Y1226-ERBB4 JM-A CYT-2 isoform ERBB4jmAcyt1s80 UBC(77-152) ERBB4jmAcyt2s80 APOE gene UBC(305-380) MyrG-p-Y419-SRC p-Y1172,Y1226-ERBB4 JM-A CYT-2 isoform GABRQ ERBB4 ADAM17 gamma-secretasecomplexERBB4 JM-A CYT-2 isoform PI(3,4,5)P3EGF-like ligands ERBB4 JM-A CYT-2 isoform EGF-like ligands ERBB4s80:p-Y694-STAT5A:CSN2 geneUBC(609-684) GABRB1 EGFR WWP1 ERBB4jmAcyt1s80 Activation of NMDAreceptors andpostsynaptic eventsGABRB3 CXCL12(22-93)ATPGABRG2 RPS27A(1-76) ERBB4jmAcyt1s80 GTPAPH1A UBC(457-532) MXD4 gene ERBB4s80 UBC(305-380) NRG2 YAP1 p21 RAS:GDPp-Y1172,Y1226-ERBB4 JM-A CYT-2 isoform ERBB4 JM-A CYT-1 isoform ESR1 ESR1 ERBB4jmAcyt1s80 CSN2 geneWWP1/ITCHNeuregulins ERBB4jmAcyt2s80 CSN2 gene TAB2 S-Farn-Me-PalmS KRAS4A PGR geneERBB4jmAcyt1s80 EGF-like ligands ESTG ERBB4jmAcyt1s80 ERBB4jmAcyt1s80 ERBB4jmAcyt1s80 ERBB4jmAcyt1s80:MXD4geneAPOE geneERBB4s80:ESR1:estrogen:CXCL12 geneESR1 ADAP1 gene CXCL12 gene APOEUBA52(1-76) PGRGRB2:SOS1:p-Y349,350-SHC1:p-ERBB4SHC1Neuregulins ERBB4NEDD4PSEN1(1-298) GABRB1 UBC(229-304) GABA ERBB4s80:ADAP1 geneERBB4s80:TAB2:NCOR1:S100B genep-ERBB4cyt1 homodimers TAB2 UBC(609-684) GABRG3 ERBB4s80:ESR1:estrogen:ERBB4 geneEGF-like ligands UBC(229-304) EGF-like ligands NRGs/EGF-likeligandsATPUb-ERBB4:WWP1/ITCHUBB(153-228) Neuregulins UBA52(1-76) UBB(153-228) STMN1 geneERBB4s80:YAP1UBB(1-76) GABRB2 p-Y1056,Y1188,Y1242-ERBB4 JM-A CYT-1 isoform NRG1 ERBB4jmAcyt1ECD ERBB4cyt1 homodimers ERBB4jmAcyt2m80 ADPp-ERBB4cyt1 homodimers Neuregulins UBC(77-152) GRB2-1 ERBB4jmAcyt1s80 ATPNeuregulins ERBB4 gene ERBB4jmAcyt1s80 ERBB4jmAcyt2s80 p-Y1056,Y1188,Y1242-ERBB4 JM-A CYT-1 isoform PGR gene MXD4ERBB4s80:WWOXERBB4/m80/s80:WWP1/ITCHNRGs/EGF-likeligands:ERBB4ADAP1ERBB4jmAcyt1s80dimerSPARCp-ERBB4cyt1 homodimers NCSTN ERBB3-1 ERBB4jmAcyt1s80:NEDD4EGF-like ligands ERBB4jmAcyt1s80 ERBB4s80:TAB2:NCOR1SHC1 ITCH GRB2-1 ERBB4jmAcyt2s80 ERBB4m80 ERBB4 JM-A CYT-1 isoform S100BDLG4WWP1 ERBB4jmAcyt1s80 p-Y349,Y350-SHC1 GABRA1 Neuregulins GABRB2 EGF-like ligands ERBB4jmAcyt2s80 MXD4 geneEGF-like ligands ERBB4jmAcyt2s80 ERBB4 JM-A CYT-1 isoform ERBB4jmAcyt1s80 ERBB3-1 ERBB4 ERBB4 homodimersERBB4s80:MyrG-p-Y419-SRCS-Farn-Me PalmS NRAS S-Farn-Me-2xPalmS HRAS ERBB4 JM-B CYT-1 isoform S-Farn-Me-2xPalmS HRAS UBC(381-456) p-Y694-STAT5A PIK3CA:PIK3R1UbRPS27A(1-76) NRG1 p-Y1172,Y1226-ERBB4 JM-A CYT-2 isoform UBC(229-304) NRG2 ERBB4 JM-A CYT-2 isoform Neuregulins UBC(533-608) ERBB4s80 SPARC geneTAB2:NCOR1ERBB4s80GDPUBA52(1-76) PIK3R1 NCOR1 ADPERBB4jmAcyt2s80 ESR1 NEDD4 p-Y694-STAT5A NRG2:p-ERBB4homodimers:GABRA1heteropentamers:GABASOS1 Neuregulins ERBB4s80:TAB2:NCOR1GDP GABRG2 UBC(533-608) ERBB4jmAcyt1s80 ERBB4jmAcyt1s80 ESR1:ESTGS-Farn-Me PalmS NRAS EGF-like ligands UBB(77-152) Neuregulins UBC(153-228) GFAP geneERBB4m80 ERBB4s80:p-Y694-STAT5AUBC(77-152) p-ERBB4cyt1homodimersp-Y1172,Y1226-ERBB4 JM-A CYT-2 isoform NRG2:p-ERBB4cyt1 homodimers S100B gene PSENEN ERBB4 JM-B CYT-1 isoform ERBB4jmAcyt2ECD RPS27A(1-76) ERBB4jmAcyt2s80 YAP1- and WWTR1(TAZ)-stimulatedgene expressionp-Y1046,Y1178,Y1232-ERBB4 JM-B CYT-1 isoform EGF-like ligands p-Y1172,Y1226-ERBB4 JM-A CYT-2 isoform ERBB4s80:STMN1 geneNRG2:p-ERBB4cyt1 homodimers SHC1:p-ERBB4MyrG-p-Y419-SRCp-Y349,Y350-SHC1 ERBB4jmAcyt1m80 UBC(1-76) ERBB4s80:p-Y694-STAT5AGABRA1heteropentamers:GABAp-Y694-STAT5A UBB(153-228) NRG1/2:ERBB3p-Y694-STAT5AhomodimerEGF-like ligands NRG2 YAP1ERBB4:EGFRheterodimerERBB4jmAcyt1s80 UBC(153-228) NCOR1 Prolactin receptorsignalingEGF-like ligands ERBB4jmAcyt1s80 NEDD4 DLG4 GABRQ GABRG3 ESTG ERBB4s80:YAP1ERBB4jmAcyt2s80 ERBB4jmAcyt2s80 ERBB4jmAcyt1s80 GRB2-1:SOS1ERBB4 CYT-1 isoforms ERBB4jmAcyt2s80 S-Farn-Me KRAS4B WWP1 S-Farn-Me KRAS4B UBC(153-228) p-Y1046,Y1178,Y1232-ERBB4 JM-B CYT-1 isoform EGF-like ligands ADAP1 geneADPUBC(1-76) ERBB4jmAcyt2s80 PIK3CA Signaling by HippoUBC(457-532) ERBB4_ECDERBB4jmAcyt2s80 p-Y1172,Y1226-ERBB4 JM-A CYT-2 isoform ESTG ERBB4jmAcyt1s80 ERBB4jmAcyt1s80 NCOR1 GFAPERBB4jmAcyt1s80 ERBB4jmAcyt2s80 PIK3CA ERBB4s80TAB2 p-ERBB4 homodimersERBB4jmAcyt1s80 EGF Neuregulins TAB2 WWOXITCH ERBB4m80APH1B ERBB4jmAcyt2s80 ERBB4m80 UBC(381-456) NRG2 GFAP gene PSEN2(1-297) EGF ERBB4s80:TAB2:NCOR1:GFAP geneNCOR1 ERBB4:ERBB3heterodimerS100B genePIK3R1 ITCH Neuregulins WWOX ERBB4s80:ESR1:estrogenNRG2:p-ERBB4homodimersERBB4jmAcyt1s80dimerCXCL12 geneERBB4s80:SPARC geneNeuregulins CSN2STMN1 gene TAB2 ADAM17Zn2+ S-Farn-Me-PalmS KRAS4A ERBB4jmAcyt2s80 YAP1 ERBB4jmAcyt2s80 PI(4,5)P2UBB(77-152) UBC(609-684) GTP ERBB4jmAcyt1s80 ERBB4 RAF/MAP kinasecascadeERBB4s80 UBB(1-76) EGF:EGFRp-Y694-STAT5A ERBB4jmAcyt1s80 p-Y349,350-SHC1:p-ERBB4ERBB4 JM-A CYT-2 isoform ERBB4 JM-A CYT-2 isoform NCOR1 ERBB4:DLG4SPARC gene UBB(1-76) ERBB4 CYT-1 isoforms UBC(381-456) ERBB4/ERBB4m80/ERBB4s80ERBB4jmAcyt2s80 ERBB4s80EGFR PI3K:p-ERBB4cyt1ERBB4jmAcyt2s80 ESTG ERBB4s80:ESR1:estrogen:PGR geneSTMN1UBC(457-532) SOS1 ERBB4jmAcyt1s80 UBB(77-152) GABA ERBB4 JM-B CYT-1 isoform p21 RAS:GTPERBB4jmAcyt1s80 UBC(1-76) ERBB4jmAcyt2s80 ERBB4 geneUb-ERBB4jmAcyt1s80:NEDD4p-ERBB4 JM-Ahomodimersp-Y1056,Y1188,Y1242-ERBB4 JM-A CYT-1 isoform p-ERBB4cyt1 homodimers ERBB4 JM-A CYT-2 isoform PIP3 activates AKTsignalingGABRB3 ERBB4s80:APOE genePSEN1(299-467) ERBB4jmAcyt2s80 PSEN2(298-448) Neuregulins ESTG UBC(533-608) 541, 34, 634516, 594-7, 9, 15...3, 12, 24, 28, 49...10, 25, 33, 753849, 744569


Description

ERBB4, also known as HER4, belongs to the ERBB family of receptors, which also includes ERBB1 (EGFR/HER1), ERBB2 (HER2/NEU) and ERBB3 (HER3). Similar to EGFR, ERBB4 has an extracellular ligand binding domain, a single transmembrane domain and a cytoplasmic domain which contains an active tyrosine kinase and a C-tail with multiple phosphorylation sites. At least three and possibly four splicing isoforms of ERBB4 exist that differ in their C-tail and/or the extracellular juxtamembrane regions: ERBB4 JM-A CYT1, ERBB4 JM-A CYT2 and ERBB4 JM-B CYT1 (the existence of ERBB4 JM-B CYT2 has not been confirmed).

ERBB4 becomes activated by binding one of its seven ligands, three of which, HB-EGF, epiregulin EPR and betacellulin BTC, are EGF-like (Elenius et al. 1997, Riese et al. 1998), while four, NRG1, NRG2, NRG3 and NRG4, belong to the related neuregulin family (Tzahar et al. 1994, Carraway et al. 1997, Zhang et al. 1997, Hayes et al. 2007). Upon ligand binding, ERBB4 forms homodimers (Sweeney et al. 2000) or it heterodimerizes with ERBB2 (Li et al. 2007). Dimers of ERBB4 undergo trans-autophosphorylation on tyrosine residues in the C-tail (Cohen et al. 1996, Kaushansky et al. 2008, Hazan et al. 1990, Li et al. 2007), triggering downstream signaling cascades. The pathway Signaling by ERBB4 only shows signaling by ERBB4 homodimers. Signaling by heterodimers of ERBB4 and ERBB2 is shown in the pathway Signaling by ERBB2. Ligand-stimulated ERBB4 is also able to form heterodimers with ligand-stimulated EGFR (Cohen et al. 1996) and ligand-stimulated ERBB3 (Riese et al. 1995). Dimers of ERBB4 with EGFR and dimers of ERBB4 with ERBB3 were demonstrated in mouse cell lines in which human ERBB4 and EGFR or ERBB3 were exogenously expressed. These heterodimers undergo trans-autophosphorylation. The promiscuous heteromerization of ERBBs adds combinatorial diversity to ERBB signaling processes. As ERBB4 binds more ligands than other ERBBs, but has restricted expression, ERBB4 expression channels responses to ERBB ligands. The signaling capabilities of the four receptors have been compared (Schulze et al. 2005).

As for other receptor tyrosine kinases, ERBB4 signaling effectors are largely dictated through binding of effector proteins to ERBB4 peptides that are phosphorylated upon ligand binding. All splicing isoforms of ERBB4 possess two tyrosine residues in the C-tail that serve as docking sites for SHC1 (Kaushansky et al. 2008, Pinkas-Kramarski et al. 1996, Cohen et al. 1996). Once bound to ERBB4, SHC1 becomes phosphorylated on tyrosine residues by the tyrosine kinase activity of ERBB4, which enables it to recruit the complex of GRB2 and SOS1, resulting in the guanyl-nucleotide exchange on RAS and activation of RAF and MAP kinase cascade (Kainulainen et al. 2000).

The CYT1 isoforms of ERBB4 also possess a C-tail tyrosine residue that, upon trans-autophosphorylation, serves as a docking site for the p85 alpha subunit of PI3K (Kaushansky et al. 2008, Cohen et al. 1996), leading to assembly of an active PI3K complex that converts PIP2 to PIP3 and activates AKT signaling (Kainulainen et al. 2000).

Besides signaling as a conventional transmembrane receptor kinase, ERBB4 differs from other ERBBs in that JM-A isoforms signal through efficient release of a soluble intracellular domain. Ligand activated homodimers of ERBB4 JM-A isoforms (ERBB4 JM-A CYT1 and ERBB4 JM-A CYT2) undergo proteolytic cleavage by ADAM17 (TACE) in the juxtamembrane region, resulting in shedding of the extracellular domain and formation of an 80 kDa membrane bound ERBB4 fragment known as ERBB4 m80 (Rio et al. 2000, Cheng et al. 2003). ERBB4 m80 undergoes further proteolytic cleavage, mediated by the gamma-secretase complex, which releases the soluble 80 kDa ERBB4 intracellular domain, known as ERBB4 s80 or E4ICD, into the cytosol (Ni et al. 2001). ERBB4 s80 is able to translocate to the nucleus, promote nuclear translocation of various transcription factors, and act as a transcription co-factor. For example, in mammary cells, ERBB4 binds SH2 transcription factor STAT5A. ERBB4 s80 shuttles STAT5A to the nucleus, and actsa as a STAT5A co-factor in binding to and promoting transcription from the beta-casein (CSN2) promoter, and may be involved in the regulation of other lactation-related genes (Jones et al. 1999, Williams et al. 2004, Muraoka-Cook et al. 2008). ERBB4 s80 binds activated estrogen receptor in the nucleus and acts as a transcriptional co-factor in promoting transcription of some estrogen-regulated genes, including progesterone receptor gene NR3C3 and CXCL12 (SDF1) (Zhu et al. 2006). In neuronal precursors, ERBB4 s80 binds the complex of TAB and NCOR1, helps to move the complex into the nucleus, and is a co-factor of TAB:NCOR1-mediated inhibition of expression of astrocyte differentiation genes GFAP and S100B (Sardi et al. 2006).

The C-tail of ERBB4 possesses several WW-domain binding motifs (three in CYT1 isoform and two in CYT2 isoform), which enable interaction of ERBB4 with WW-domain containing proteins. ERBB4 s80, through WW-domain binding motifs, interacts with YAP1 transcription factor, a known proto-oncogene, and is a co-regulator of YAP1-mediated transcription in association with TEAD transcription factors (Komuro et al. 2003, Omerovic et al. 2004). Hence, the WW binding motif couples ERBB4 to the major effector arm of the HIPPO signaling pathway. The tumor suppressor WWOX, another WW-domain containing protein, competes with YAP1 in binding to ERBB4 s80 and prevents translocation of ERBB4 s80 to the nucleus (Aqeilan et al. 2005).

WW-domain binding motifs in the C-tail of ERBB4 play an important role in the downregulation of ERBB4 receptor signaling, enabling the interaction of intact ERBB4, ERBB4 m80 and ERBB4 s80 with NEDD4 family of E3 ubiquitin ligases WWP1 and ITCH. The interaction of WWP1 and ITCH with intact ERBB4 is independent of receptor activation and autophosphorylation. Binding of WWP1 and ITCH ubiquitin ligases leads to ubiquitination of ERBB4 and its cleavage products, and subsequent degradation through both proteasomal and lysosomal routes (Omerovic et al. 2007, Feng et al. 2009). In addition, the s80 cleavage product of ERBB4 JM-A CYT-1 isoform is the target of NEDD4 ubiquitin ligase. NEDD4 binds ERBB4 JM-A CYT-1 s80 (ERBB4jmAcyt1s80) through its PIK3R1 interaction site and mediates ERBB4jmAcyt1s80 ubiquitination, thereby decreasing the amount of ERBB4jmAcyt1s80 that reaches the nucleus (Zeng et al. 2009).

ERBB4 also binds the E3 ubiquitin ligase MDM2, and inhibitor of p53 (Arasada et al. 2005). Other proteins that bind to ERBB4 intracellular domain have been identified by co-immunoprecipitation and mass spectrometry (Gilmore-Hebert et al., 2010), and include transcriptional co-repressor TRIM28/KAP1, which promotes chromatin compaction. DNA damage signaling through ATM releases TRIM28-associated heterochromatinization. Interactions of ERBB4 with TRIM28 and MDM2 may be important for integration of growth factor responses and DNA damage responses.

In human breast cancer cell lines, ERBB4 activation enhances anchorage-independent colony formation in soft agar but inhibits cell growth in a monolayer culture. Different ERBB4 ligands induce different gene expression changes in breast cancer cell lines. Some of the genes induced in response to ERBB4 signaling in breast cancer cell lines are RAB2, EPS15R and GATA4. It is not known if these gene are direct transcriptional targets of ERBB4 (Amin et al. 2004).

Transcriptome and ChIP-seq comparisons of full-length and intracellular domain isoforms in isogenic MCF10A mammary cell background have revealed the diversification of ERBB4 signaling engendered by alternative splicing and cleavage (Wali et al., 2014). ERBB4 broadly affected protease expression, cholesterol biosynthesis, HIF1-alpha signaling, and HIPPO signaling pathways, and other pathways were differentially activated by CYT1 and CYT2 isoforms. For example, CYT1 promoted expression of transcription factors TWIST1 and SNAIL1 that promote epithelial-mesenchymal transition. HIF1-alpha and HIPPO signaling are mediated, respectively, by binding of ERBB4 to HIF1-alpha and to YAP (Paatero et al., 2012, Komuro et al., 2003). ERBB4 increases activity of the transcription factor SREBF2, resulting in increased expression of SREBF2-target genes involved in cholesterol biosynthesis. The mechanism is not known and may involve facilitation of SREBF2 cleavage through ERBB4-mediated PI3K signaling (Haskins et al. 2016).

In some contexts, ERBB4 promotes growth suppression or apoptosis (Penington et al., 2002). Activation of ERBB4 in breast cancer cell lines leads to JNK dependent increase in BRCA1 mRNA level and mitotic cell cycle delay, but the exact mechanism has not been elucidated (Muraoka Cook et al. 2006). The nature of growth responses may be connected with the spliced isoforms expressed. In comparisons of CYT1 vs CYT2 (full-length and ICD) expression in mammary cells, CYT1 was a weaker growth inducer, associated with attenuated MAPK signaling relative to CYT2 (Wali et al., 2014). ERBB4 s80 is also able to translocate to the mitochondrial matrix, presumably when its nuclear translocation is inhibited. Once in the mitochondrion, the BH3 domain of ERBB4, characteristic of BCL2 family members, may enable it to act as a pro apoptotic factor (Naresh et al. 2006).

ERBB4 plays important roles in the developing and adult nervous system. Erbb4 deficiency in somatostatin-expressing neurons of the thalamic reticular nucleus alters behaviors dependent on sensory selection (Ahrens et al. 2015). NRG1-activated ERBB4 signaling enhances AMPA receptor responses through PKC-dependent AMPA receptor exocytosis. This results in an increased excitatory input to parvalbumin-expressing inhibitory neurons in the visual cortex and regulates visual cortical plasticity (Sun et al. 2016). NRG1-activated ERBB4 signaling is involved in GABAergic activity in amygdala which mediates fear conditioning (fear memory) (Lu et al. 2014). Conditional Erbb4 deletion from fast-spiking interneurons, chandelier and basket cells of the cerebral cortex leads to synaptic defects associated with increased locomotor activity and abnormal emotional, social and cognitive function that can be linked to some of the schizophrenia features. The level of GAD1 (GAD67) protein is reduced in the cortex of conditional Erbb4 mutants. GAD1 is a GABA synthesizing enzyme. Cortical mRNA levels of GAD67 are consistently decreased in schizophrenia (Del Pino et al. 2014). Erbb4 is expressed in the GABAergic neurons of the bed nucleus stria terminalis, a part of the extended amygdala. Inhibition of NRG1-triggered ERBB4 signaling induces anxiety-like behavior, which depends on GABAergic neurotransmission. NRG1-ERBB4 signaling stimulates presynaptic GABA release, but the exact mechanism is not known (Geng et al. 2016). NRG1 protects cortical interneurons against ischemic brain injury through ERBB4-mediated increase in GABAergic transmission (Guan et al. 2015). NRG2-activated ERBB4 can reduce the duration of GABAergic transmission by binding to GABA receptors at the postsynaptic membrane via their GABRA1 subunit and promoting endocytosis of GABA receptors (Mitchell et al. 2013). NRG1 promotes synchronization of prefrontal cortex interneurons in an ERBB4 dependent manner (Hou et al. 2014). NRG1-ERBB4 signaling protects neurons from the cell death induced by a mutant form of the amyloid precursor protein (APP) (Woo et al. 2012).

Clinical relevance of ERBB4 has been identified in several contexts. In cancer, putative and validated gain-of-function mutations or gene amplification that may be drivers have been identified at modest frequencies, and may also contribute to resistance to EGFR and ERBB2-targeted therapies. This is noteworthy as ERBB4 kinase activity is inhibited by pan-ERBB tyrosine kinase inhibitors, including lapatinib, which is approved by the US FDA. The reduced prevalence relative to EGFR and ERBB2 in cancer may reflect more restricted expression of ERBB4, or differential signaling, as specific ERBB4 isoforms have been linked to growth inhibition or apoptosis in experimental systems. ERBB2/ERBB4 heterodimers protect cardiomyocytes, so reduced activity of ERBB4 in patients treated with the ERBB2-targeted therapeutic antibody trastuzumab may contribute to the cardiotoxicity of this agent when used in combination with (cardiotoxic) anthracyclines.

With the importance of ERBB4 in developing and adult nervous system, NRG1 and/or ERBB4 polymorphisms, splicing aberrations and mutations have been linked to nervous system disorders including schizophrenia and amyotrophic lateral sclerosis, although these findings are not yet definitive. View original pathway at Reactome.

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Bibliography

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  1. Goffin V, Binart N, Touraine P, Kelly PA.; ''Prolactin: the new biology of an old hormone.''; PubMed Europe PMC Scholia
  2. Schuchardt BJ, Bhat V, Mikles DC, McDonald CB, Sudol M, Farooq A.; ''Molecular origin of the binding of WWOX tumor suppressor to ErbB4 receptor tyrosine kinase.''; PubMed Europe PMC Scholia
  3. Oka T, Remue E, Meerschaert K, Vanloo B, Boucherie C, Gfeller D, Bader GD, Sidhu SS, Vandekerckhove J, Gettemans J, Sudol M.; ''Functional complexes between YAP2 and ZO-2 are PDZ domain-dependent, and regulate YAP2 nuclear localization and signalling.''; PubMed Europe PMC Scholia
  4. Roskoski R.; ''RAF protein-serine/threonine kinases: structure and regulation.''; PubMed Europe PMC Scholia
  5. McKay MM, Morrison DK.; ''Integrating signals from RTKs to ERK/MAPK.''; PubMed Europe PMC Scholia
  6. Plotnikov A, Zehorai E, Procaccia S, Seger R.; ''The MAPK cascades: signaling components, nuclear roles and mechanisms of nuclear translocation.''; PubMed Europe PMC Scholia
  7. Wellbrock C, Karasarides M, Marais R.; ''The RAF proteins take centre stage.''; PubMed Europe PMC Scholia
  8. Muraoka-Cook RS, Sandahl MA, Strunk KE, Miraglia LC, Husted C, Hunter DM, Elenius K, Chodosh LA, Earp HS.; ''ErbB4 splice variants Cyt1 and Cyt2 differ by 16 amino acids and exert opposing effects on the mammary epithelium in vivo.''; PubMed Europe PMC Scholia
  9. Roberts PJ, Der CJ.; ''Targeting the Raf-MEK-ERK mitogen-activated protein kinase cascade for the treatment of cancer.''; PubMed Europe PMC Scholia
  10. Traynelis SF, Wollmuth LP, McBain CJ, Menniti FS, Vance KM, Ogden KK, Hansen KB, Yuan H, Myers SJ, Dingledine R.; ''Glutamate receptor ion channels: structure, regulation, and function.''; PubMed Europe PMC Scholia
  11. Rio C, Buxbaum JD, Peschon JJ, Corfas G.; ''Tumor necrosis factor-alpha-converting enzyme is required for cleavage of erbB4/HER4.''; PubMed Europe PMC Scholia
  12. Varelas X, Miller BW, Sopko R, Song S, Gregorieff A, Fellouse FA, Sakuma R, Pawson T, Hunziker W, McNeill H, Wrana JL, Attisano L.; ''The Hippo pathway regulates Wnt/beta-catenin signaling.''; PubMed Europe PMC Scholia
  13. Aqeilan RI, Donati V, Palamarchuk A, Trapasso F, Kaou M, Pekarsky Y, Sudol M, Croce CM.; ''WW domain-containing proteins, WWOX and YAP, compete for interaction with ErbB-4 and modulate its transcriptional function.''; PubMed Europe PMC Scholia
  14. Carraway KL, Weber JL, Unger MJ, Ledesma J, Yu N, Gassmann M, Lai C.; ''Neuregulin-2, a new ligand of ErbB3/ErbB4-receptor tyrosine kinases.''; PubMed Europe PMC Scholia
  15. Davies H, Bignell GR, Cox C, Stephens P, Edkins S, Clegg S, Teague J, Woffendin H, Garnett MJ, Bottomley W, Davis N, Dicks E, Ewing R, Floyd Y, Gray K, Hall S, Hawes R, Hughes J, Kosmidou V, Menzies A, Mould C, Parker A, Stevens C, Watt S, Hooper S, Wilson R, Jayatilake H, Gusterson BA, Cooper C, Shipley J, Hargrave D, Pritchard-Jones K, Maitland N, Chenevix-Trench G, Riggins GJ, Bigner DD, Palmieri G, Cossu A, Flanagan A, Nicholson A, Ho JW, Leung SY, Yuen ST, Weber BL, Seigler HF, Darrow TL, Paterson H, Marais R, Marshall CJ, Wooster R, Stratton MR, Futreal PA.; ''Mutations of the BRAF gene in human cancer.''; PubMed Europe PMC Scholia
  16. Chardin P, Camonis JH, Gale NW, van Aelst L, Schlessinger J, Wigler MH, Bar-Sagi D.; ''Human Sos1: a guanine nucleotide exchange factor for Ras that binds to GRB2.''; PubMed Europe PMC Scholia
  17. Riese DJ, van Raaij TM, Plowman GD, Andrews GC, Stern DF.; ''The cellular response to neuregulins is governed by complex interactions of the erbB receptor family.''; PubMed Europe PMC Scholia
  18. Roskoski R.; ''ERK1/2 MAP kinases: structure, function, and regulation.''; PubMed Europe PMC Scholia
  19. Kaushansky A, Gordus A, Budnik BA, Lane WS, Rush J, MacBeath G.; ''System-wide investigation of ErbB4 reveals 19 sites of Tyr phosphorylation that are unusually selective in their recruitment properties.''; PubMed Europe PMC Scholia
  20. Turjanski AG, Vaqué JP, Gutkind JS.; ''MAP kinases and the control of nuclear events.''; PubMed Europe PMC Scholia
  21. Brown MD, Sacks DB.; ''Protein scaffolds in MAP kinase signalling.''; PubMed Europe PMC Scholia
  22. Hayes NV, Blackburn E, Smart LV, Boyle MM, Russell GA, Frost TM, Morgan BJ, Baines AJ, Gullick WJ.; ''Identification and characterization of novel spliced variants of neuregulin 4 in prostate cancer.''; PubMed Europe PMC Scholia
  23. Ni CY, Murphy MP, Golde TE, Carpenter G.; ''gamma -Secretase cleavage and nuclear localization of ErbB-4 receptor tyrosine kinase.''; PubMed Europe PMC Scholia
  24. Pan D.; ''The hippo signaling pathway in development and cancer.''; PubMed Europe PMC Scholia
  25. Paoletti P, Bellone C, Zhou Q.; ''NMDA receptor subunit diversity: impact on receptor properties, synaptic plasticity and disease.''; PubMed Europe PMC Scholia
  26. Zeng F, Xu J, Harris RC.; ''Nedd4 mediates ErbB4 JM-a/CYT-1 ICD ubiquitination and degradation in MDCK II cells.''; PubMed Europe PMC Scholia
  27. Williams CC, Allison JG, Vidal GA, Burow ME, Beckman BS, Marrero L, Jones FE.; ''The ERBB4/HER4 receptor tyrosine kinase regulates gene expression by functioning as a STAT5A nuclear chaperone.''; PubMed Europe PMC Scholia
  28. Lee KK, Ohyama T, Yajima N, Tsubuki S, Yonehara S.; ''MST, a physiological caspase substrate, highly sensitizes apoptosis both upstream and downstream of caspase activation.''; PubMed Europe PMC Scholia
  29. Tzahar E, Levkowitz G, Karunagaran D, Yi L, Peles E, Lavi S, Chang D, Liu N, Yayon A, Wen D.; ''ErbB-3 and ErbB-4 function as the respective low and high affinity receptors of all Neu differentiation factor/heregulin isoforms.''; PubMed Europe PMC Scholia
  30. Gilmore-Hebert M, Ramabhadran R, Stern DF.; ''Interactions of ErbB4 and Kap1 connect the growth factor and DNA damage response pathways.''; PubMed Europe PMC Scholia
  31. Haskins JW, Zhang S, Means RE, Kelleher JK, Cline GW, Canfrán-Duque A, Suárez Y, Stern DF.; ''Neuregulin-activated ERBB4 induces the SREBP-2 cholesterol biosynthetic pathway and increases low-density lipoprotein uptake.''; PubMed Europe PMC Scholia
  32. Geng F, Zhang J, Wu JL, Zou WJ, Liang ZP, Bi LL, Liu JH, Kong Y, Huang CQ, Li XW, Yang JM, Gao TM.; ''Neuregulin 1-ErbB4 signaling in the bed nucleus of the stria terminalis regulates anxiety-like behavior.''; PubMed Europe PMC Scholia
  33. Cohen S, Greenberg ME.; ''Communication between the synapse and the nucleus in neuronal development, plasticity, and disease.''; PubMed Europe PMC Scholia
  34. Kelly PA, Binart N, Freemark M, Lucas B, Goffin V, Bouchard B.; ''Prolactin receptor signal transduction pathways and actions determined in prolactin receptor knockout mice.''; PubMed Europe PMC Scholia
  35. Li Z, Mei Y, Liu X, Zhou M.; ''Neuregulin-1 only induces trans-phosphorylation between ErbB receptor heterodimer partners.''; PubMed Europe PMC Scholia
  36. Feng SM, Muraoka-Cook RS, Hunter D, Sandahl MA, Caskey LS, Miyazawa K, Atfi A, Earp HS.; ''The E3 ubiquitin ligase WWP1 selectively targets HER4 and its proteolytically derived signaling isoforms for degradation.''; PubMed Europe PMC Scholia
  37. Muraoka-Cook RS, Caskey LS, Sandahl MA, Hunter DM, Husted C, Strunk KE, Sartor CI, Rearick WA, McCall W, Sgagias MK, Cowan KH, Earp HS.; ''Heregulin-dependent delay in mitotic progression requires HER4 and BRCA1.''; PubMed Europe PMC Scholia
  38. Zhu Y, Sullivan LL, Nair SS, Williams CC, Pandey AK, Marrero L, Vadlamudi RK, Jones FE.; ''Coregulation of estrogen receptor by ERBB4/HER4 establishes a growth-promoting autocrine signal in breast tumor cells.''; PubMed Europe PMC Scholia
  39. Hou XJ, Ni KM, Yang JM, Li XM.; ''Neuregulin 1/ErbB4 enhances synchronized oscillations of prefrontal cortex neurons via inhibitory synapses.''; PubMed Europe PMC Scholia
  40. Omerovic J, Puggioni EM, Napoletano S, Visco V, Fraioli R, Frati L, Gulino A, Alimandi M.; ''Ligand-regulated association of ErbB-4 to the transcriptional co-activator YAP65 controls transcription at the nuclear level.''; PubMed Europe PMC Scholia
  41. Arasada RR, Carpenter G.; ''Secretase-dependent tyrosine phosphorylation of Mdm2 by the ErbB-4 intracellular domain fragment.''; PubMed Europe PMC Scholia
  42. Elenius K, Paul S, Allison G, Sun J, Klagsbrun M.; ''Activation of HER4 by heparin-binding EGF-like growth factor stimulates chemotaxis but not proliferation.''; PubMed Europe PMC Scholia
  43. Del Pino I, García-Frigola C, Dehorter N, Brotons-Mas JR, Alvarez-Salvado E, Martínez de Lagrán M, Ciceri G, Gabaldón MV, Moratal D, Dierssen M, Canals S, Marín O, Rico B.; ''Erbb4 deletion from fast-spiking interneurons causes schizophrenia-like phenotypes.''; PubMed Europe PMC Scholia
  44. Riese DJ, Komurasaki T, Plowman GD, Stern DF.; ''Activation of ErbB4 by the bifunctional epidermal growth factor family hormone epiregulin is regulated by ErbB2.''; PubMed Europe PMC Scholia
  45. Sardi SP, Murtie J, Koirala S, Patten BA, Corfas G.; ''Presenilin-dependent ErbB4 nuclear signaling regulates the timing of astrogenesis in the developing brain.''; PubMed Europe PMC Scholia
  46. Omerovic J, Santangelo L, Puggioni EM, Marrocco J, Dall'Armi C, Palumbo C, Belleudi F, Di Marcotullio L, Frati L, Torrisi MR, Cesareni G, Gulino A, Alimandi M.; ''The E3 ligase Aip4/Itch ubiquitinates and targets ErbB-4 for degradation.''; PubMed Europe PMC Scholia
  47. Cargnello M, Roux PP.; ''Activation and function of the MAPKs and their substrates, the MAPK-activated protein kinases.''; PubMed Europe PMC Scholia
  48. Sun Y, Ikrar T, Davis MF, Gong N, Zheng X, Luo ZD, Lai C, Mei L, Holmes TC, Gandhi SP, Xu X.; ''Neuregulin-1/ErbB4 Signaling Regulates Visual Cortical Plasticity.''; PubMed Europe PMC Scholia
  49. Oh H, Irvine KD.; ''Yorkie: the final destination of Hippo signaling.''; PubMed Europe PMC Scholia
  50. Cantwell-Dorris ER, O'Leary JJ, Sheils OM.; ''BRAFV600E: implications for carcinogenesis and molecular therapy.''; PubMed Europe PMC Scholia
  51. Xiao L, Chen Y, Ji M, Dong J.; ''KIBRA regulates Hippo signaling activity via interactions with large tumor suppressor kinases.''; PubMed Europe PMC Scholia
  52. Remue E, Meerschaert K, Oka T, Boucherie C, Vandekerckhove J, Sudol M, Gettemans J.; ''TAZ interacts with zonula occludens-1 and -2 proteins in a PDZ-1 dependent manner.''; PubMed Europe PMC Scholia
  53. Cohen BD, Green JM, Foy L, Fell HP.; ''HER4-mediated biological and biochemical properties in NIH 3T3 cells. Evidence for HER1-HER4 heterodimers.''; PubMed Europe PMC Scholia
  54. Andersson ER, Lendahl U.; ''Therapeutic modulation of Notch signalling--are we there yet?''; PubMed Europe PMC Scholia
  55. Sweeney C, Lai C, Riese DJ, Diamonti AJ, Cantley LC, Carraway KL.; ''Ligand discrimination in signaling through an ErbB4 receptor homodimer.''; PubMed Europe PMC Scholia
  56. Woo RS, Lee JH, Kim HS, Baek CH, Song DY, Suh YH, Baik TK.; ''Neuregulin-1 protects against neurotoxicities induced by Swedish amyloid precursor protein via the ErbB4 receptor.''; PubMed Europe PMC Scholia
  57. Zhang D, Sliwkowski MX, Mark M, Frantz G, Akita R, Sun Y, Hillan K, Crowley C, Brush J, Godowski PJ.; ''Neuregulin-3 (NRG3): a novel neural tissue-enriched protein that binds and activates ErbB4.''; PubMed Europe PMC Scholia
  58. Paatero I, Jokilammi A, Heikkinen PT, Iljin K, Kallioniemi OP, Jones FE, Jaakkola PM, Elenius K.; ''Interaction with ErbB4 promotes hypoxia-inducible factor-1α signaling.''; PubMed Europe PMC Scholia
  59. Fukumoto T, Kubota Y, Kitanaka A, Yamaoka G, Ohara-Waki F, Imataki O, Ohnishi H, Ishida T, Tanaka T.; ''Gab1 transduces PI3K-mediated erythropoietin signals to the Erk pathway and regulates erythropoietin-dependent proliferation and survival of erythroid cells.''; PubMed Europe PMC Scholia
  60. Kyriakis JM, Avruch J.; ''Mammalian MAPK signal transduction pathways activated by stress and inflammation: a 10-year update.''; PubMed Europe PMC Scholia
  61. Guan YF, Wu CY, Fang YY, Zeng YN, Luo ZY, Li SJ, Li XW, Zhu XH, Mei L, Gao TM.; ''Neuregulin 1 protects against ischemic brain injury via ErbB4 receptors by increasing GABAergic transmission.''; PubMed Europe PMC Scholia
  62. Schulze WX, Deng L, Mann M.; ''Phosphotyrosine interactome of the ErbB-receptor kinase family.''; PubMed Europe PMC Scholia
  63. Bole-Feysot C, Goffin V, Edery M, Binart N, Kelly PA.; ''Prolactin (PRL) and its receptor: actions, signal transduction pathways and phenotypes observed in PRL receptor knockout mice.''; PubMed Europe PMC Scholia
  64. Zhao B, Li L, Lei Q, Guan KL.; ''The Hippo-YAP pathway in organ size control and tumorigenesis: an updated version.''; PubMed Europe PMC Scholia
  65. Kainulainen V, Sundvall M, Määttä JA, Santiestevan E, Klagsbrun M, Elenius K.; ''A natural ErbB4 isoform that does not activate phosphoinositide 3-kinase mediates proliferation but not survival or chemotaxis.''; PubMed Europe PMC Scholia
  66. Naresh A, Long W, Vidal GA, Wimley WC, Marrero L, Sartor CI, Tovey S, Cooke TG, Bartlett JM, Jones FE.; ''The ERBB4/HER4 intracellular domain 4ICD is a BH3-only protein promoting apoptosis of breast cancer cells.''; PubMed Europe PMC Scholia
  67. Mitchell RM, Janssen MJ, Karavanova I, Vullhorst D, Furth K, Makusky A, Markey SP, Buonanno A.; ''ErbB4 reduces synaptic GABAA currents independent of its receptor tyrosine kinase activity.''; PubMed Europe PMC Scholia
  68. Sudol M, Harvey KF.; ''Modularity in the Hippo signaling pathway.''; PubMed Europe PMC Scholia
  69. Ishibashi K, Fukumoto Y, Hasegawa H, Abe K, Kubota S, Aoyama K, Kubota S, Nakayama Y, Yamaguchi N.; ''Nuclear ErbB4 signaling through H3K9me3 is antagonized by EGFR-activated c-Src.''; PubMed Europe PMC Scholia
  70. Pinkas-Kramarski R, Soussan L, Waterman H, Levkowitz G, Alroy I, Klapper L, Lavi S, Seger R, Ratzkin BJ, Sela M, Yarden Y.; ''Diversification of Neu differentiation factor and epidermal growth factor signaling by combinatorial receptor interactions.''; PubMed Europe PMC Scholia
  71. Amin DN, Perkins AS, Stern DF.; ''Gene expression profiling of ErbB receptor and ligand-dependent transcription.''; PubMed Europe PMC Scholia
  72. Lu Y, Sun XD, Hou FQ, Bi LL, Yin DM, Liu F, Chen YJ, Bean JC, Jiao HF, Liu X, Li BM, Xiong WC, Gao TM, Mei L.; ''Maintenance of GABAergic activity by neuregulin 1-ErbB4 in amygdala for fear memory.''; PubMed Europe PMC Scholia
  73. Chan SW, Lim CJ, Chong YF, Pobbati AV, Huang C, Hong W.; ''Hippo pathway-independent restriction of TAZ and YAP by angiomotin.''; PubMed Europe PMC Scholia
  74. Murakami M, Nakagawa M, Olson EN, Nakagawa O.; ''A WW domain protein TAZ is a critical coactivator for TBX5, a transcription factor implicated in Holt-Oram syndrome.''; PubMed Europe PMC Scholia
  75. Hardingham GE, Bading H.; ''Synaptic versus extrasynaptic NMDA receptor signalling: implications for neurodegenerative disorders.''; PubMed Europe PMC Scholia
  76. Jones FE, Welte T, Fu XY, Stern DF.; ''ErbB4 signaling in the mammary gland is required for lobuloalveolar development and Stat5 activation during lactation.''; PubMed Europe PMC Scholia
  77. Penington DJ, Bryant I, Riese DJ.; ''Constitutively active ErbB4 and ErbB2 mutants exhibit distinct biological activities.''; PubMed Europe PMC Scholia
  78. Cseh B, Doma E, Baccarini M.; ''"RAF" neighborhood: protein-protein interaction in the Raf/Mek/Erk pathway.''; PubMed Europe PMC Scholia
  79. Roskoski R.; ''MEK1/2 dual-specificity protein kinases: structure and regulation.''; PubMed Europe PMC Scholia
  80. Cheng QC, Tikhomirov O, Zhou W, Carpenter G.; ''Ectodomain cleavage of ErbB-4: characterization of the cleavage site and m80 fragment.''; PubMed Europe PMC Scholia
  81. Wali VB, Haskins JW, Gilmore-Hebert M, Platt JT, Liu Z, Stern DF.; ''Convergent and divergent cellular responses by ErbB4 isoforms in mammary epithelial cells.''; PubMed Europe PMC Scholia
  82. Ahrens S, Jaramillo S, Yu K, Ghosh S, Hwang GR, Paik R, Lai C, He M, Huang ZJ, Li B.; ''ErbB4 regulation of a thalamic reticular nucleus circuit for sensory selection.''; PubMed Europe PMC Scholia
  83. Komuro A, Nagai M, Navin NE, Sudol M.; ''WW domain-containing protein YAP associates with ErbB-4 and acts as a co-transcriptional activator for the carboxyl-terminal fragment of ErbB-4 that translocates to the nucleus.''; PubMed Europe PMC Scholia
  84. Hazan R, Margolis B, Dombalagian M, Ullrich A, Zilberstein A, Schlessinger J.; ''Identification of autophosphorylation sites of HER2/neu.''; PubMed Europe PMC Scholia
  85. Muraoka-Cook RS, Sandahl M, Hunter D, Miraglia L, Earp HS.; ''Prolactin and ErbB4/HER4 signaling interact via Janus kinase 2 to induce mammary epithelial cell gene expression differentiation.''; PubMed Europe PMC Scholia

History

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CompareRevisionActionTimeUserComment
115045view16:58, 25 January 2021ReactomeTeamReactome version 75
113489view11:56, 2 November 2020ReactomeTeamReactome version 74
112689view16:08, 9 October 2020ReactomeTeamReactome version 73
101606view11:47, 1 November 2018ReactomeTeamreactome version 66
101143view21:33, 31 October 2018ReactomeTeamreactome version 65
100671view20:06, 31 October 2018ReactomeTeamreactome version 64
100221view16:51, 31 October 2018ReactomeTeamreactome version 63
99772view15:17, 31 October 2018ReactomeTeamreactome version 62 (2nd attempt)
99330view12:47, 31 October 2018ReactomeTeamreactome version 62
94018view13:51, 16 August 2017ReactomeTeamreactome version 61
93637view11:29, 9 August 2017ReactomeTeamreactome version 61
87122view18:39, 18 July 2016EgonwOntology Term : 'signaling pathway' added !
86752view09:25, 11 July 2016ReactomeTeamreactome version 56
83405view11:08, 18 November 2015ReactomeTeamVersion54
81605view13:08, 21 August 2015ReactomeTeamVersion53
77063view08:36, 17 July 2014ReactomeTeamFixed remaining interactions
76768view12:13, 16 July 2014ReactomeTeamFixed remaining interactions
76091view10:15, 11 June 2014ReactomeTeamRe-fixing comment source
75802view11:34, 10 June 2014ReactomeTeamReactome 48 Update
75153view14:10, 8 May 2014AnweshaFixing comment source for displaying WikiPathways description
74800view08:53, 30 April 2014ReactomeTeamNew pathway

External references

DataNodes

View all...
NameTypeDatabase referenceComment
ADAM17 ProteinP78536 (Uniprot-TrEMBL)
ADAM17ComplexR-HSA-1251963 (Reactome)
ADAP1 gene ProteinENSG00000105963 (Ensembl)
ADAP1 geneGeneProductENSG00000105963 (Ensembl)
ADAP1ProteinO75689 (Uniprot-TrEMBL)
ADPMetaboliteCHEBI:456216 (ChEBI)
APH1A ProteinQ96BI3 (Uniprot-TrEMBL)
APH1B ProteinQ8WW43 (Uniprot-TrEMBL)
APOE gene ProteinENSG00000130203 (Ensembl)
APOE geneGeneProductENSG00000130203 (Ensembl)
APOEProteinP02649 (Uniprot-TrEMBL)
ATPMetaboliteCHEBI:30616 (ChEBI)
Activation of NMDA

receptors and

postsynaptic events
PathwayR-HSA-442755 (Reactome) NMDA receptors are a subtype of ionotropic glutamate receptors that are specifically activated by a glutamate agonist N-methyl-D-aspartate (NMDA). Activation of NMDA receptors involves opening of the ion channel that allows the influx of Ca2+. NMDA receptors are central to activity dependent changes in synaptic strength and are predominantly involved in the synaptic plasticity that pertains to learning and memory. A unique feature of NMDA receptors, unlike other glutamate receptors, is the requirement for dual activation, both voltage-dependent and ligand-dependent activation. The ligand-dependent activation of NMDA receptors requires co-activation by two ligands, glutamate and glycine. However, at resting membrane potential, the pore of ligand-bound NMDA receptors is blocked by Mg2+. The voltage dependent Mg2+ block is relieved upon depolarization of the post-synaptic membrane. NMDA receptors are coincidence detectors, and are activated only if there is a simultaneous activation of both pre- and post-synaptic cell. Upon activation, NMDA receptors allow the influx of Ca2+ that initiates various molecular signaling cascades involved in the processes of learning and memory. For review, please refer to Cohen and Greenberg 2008, Hardingham and Bading 2010, Traynelis et al. 2010, and Paoletti et al. 2013.
CSN2 gene ProteinENSG00000135222 (Ensembl)
CSN2 geneGeneProductENSG00000135222 (Ensembl)
CSN2ProteinP05814 (Uniprot-TrEMBL)
CXCL12 gene ProteinENSG00000107562 (Ensembl)
CXCL12 geneGeneProductENSG00000107562 (Ensembl)
CXCL12(22-93)ProteinP48061 (Uniprot-TrEMBL)
DLG4 ProteinP78352 (Uniprot-TrEMBL)
DLG4ProteinP78352 (Uniprot-TrEMBL)
EGF ProteinP01133 (Uniprot-TrEMBL)
EGF-like ligands R-HSA-1233230 (Reactome)
EGF:EGFRComplexR-HSA-179847 (Reactome)
EGFR ProteinP00533 (Uniprot-TrEMBL)
ERBB3-1 ProteinP21860-1 (Uniprot-TrEMBL)
ERBB4 CYT-1 isoforms R-HSA-1233231 (Reactome)
ERBB4 JM-A CYT-1 isoform ProteinQ15303-1 (Uniprot-TrEMBL)
ERBB4 JM-A CYT-2 isoform ProteinQ15303-3 (Uniprot-TrEMBL)
ERBB4 JM-B CYT-1 isoform ProteinQ15303-2 (Uniprot-TrEMBL)
ERBB4 R-HSA-1233235 (Reactome)
ERBB4 gene ProteinENSG00000178568 (Ensembl)
ERBB4 geneGeneProductENSG00000178568 (Ensembl)
ERBB4 homodimersComplexR-HSA-1250221 (Reactome)
ERBB4/ERBB4m80/ERBB4s80ComplexR-HSA-1253281 (Reactome)
ERBB4/m80/s80:WWP1/ITCHComplexR-HSA-1253284 (Reactome)
ERBB4:DLG4ComplexR-HSA-9612575 (Reactome)
ERBB4:EGFR heterodimerComplexR-HSA-1977956 (Reactome)
ERBB4:ERBB3 heterodimerComplexR-HSA-1977955 (Reactome)
ERBB4ComplexR-HSA-1233235 (Reactome)
ERBB4_ECDComplexR-HSA-1251970 (Reactome)
ERBB4cyt1 homodimers R-HSA-1250318 (Reactome)
ERBB4jmAcyt1ECD ProteinQ15303-1 (Uniprot-TrEMBL)
ERBB4jmAcyt1m80 ProteinQ15303-1 (Uniprot-TrEMBL)
ERBB4jmAcyt1s80 dimerComplexR-HSA-1252008 (Reactome)
ERBB4jmAcyt1s80 dimerComplexR-HSA-1252015 (Reactome)
ERBB4jmAcyt1s80 ProteinQ15303-1 (Uniprot-TrEMBL)
ERBB4jmAcyt1s80:MXD4 geneComplexR-HSA-9612446 (Reactome)
ERBB4jmAcyt1s80:NEDD4ComplexR-HSA-1973959 (Reactome)
ERBB4jmAcyt2ECD ProteinQ15303-3 (Uniprot-TrEMBL)
ERBB4jmAcyt2m80 ProteinQ15303-3 (Uniprot-TrEMBL)
ERBB4jmAcyt2s80 ProteinQ15303-3 (Uniprot-TrEMBL)
ERBB4m80 R-HSA-1251960 (Reactome)
ERBB4m80ComplexR-HSA-1251960 (Reactome)
ERBB4s80 R-HSA-1251980 (Reactome)
ERBB4s80:ADAP1 geneComplexR-HSA-9612270 (Reactome)
ERBB4s80:APOE geneComplexR-HSA-9612240 (Reactome)
ERBB4s80:ESR1:estrogen:CXCL12 geneComplexR-HSA-8954210 (Reactome)
ERBB4s80:ESR1:estrogen:ERBB4 geneComplexR-HSA-9612668 (Reactome)
ERBB4s80:ESR1:estrogen:PGR geneComplexR-HSA-8954204 (Reactome)
ERBB4s80:ESR1:estrogenComplexR-HSA-1254397 (Reactome)
ERBB4s80:MyrG-p-Y419-SRCComplexR-HSA-9612227 (Reactome)
ERBB4s80:SPARC geneComplexR-HSA-9612287 (Reactome)
ERBB4s80:STMN1 geneComplexR-HSA-9612450 (Reactome)
ERBB4s80:TAB2:NCOR1:GFAP geneComplexR-HSA-8954171 (Reactome)
ERBB4s80:TAB2:NCOR1:S100B geneComplexR-HSA-8954176 (Reactome)
ERBB4s80:TAB2:NCOR1ComplexR-HSA-1253326 (Reactome)
ERBB4s80:TAB2:NCOR1ComplexR-HSA-1253328 (Reactome)
ERBB4s80:WWOXComplexR-HSA-1253344 (Reactome)
ERBB4s80:YAP1ComplexR-HSA-1253341 (Reactome)
ERBB4s80:YAP1ComplexR-HSA-1253347 (Reactome)
ERBB4s80:p-Y694-STAT5A:CSN2 geneComplexR-HSA-8954223 (Reactome)
ERBB4s80:p-Y694-STAT5AComplexR-HSA-1254284 (Reactome)
ERBB4s80:p-Y694-STAT5AComplexR-HSA-1254288 (Reactome)
ERBB4s80ComplexR-HSA-1251980 (Reactome)
ERBB4s80ComplexR-HSA-1252016 (Reactome)
ERBB4s80ComplexR-HSA-1254403 (Reactome)
ESR1 ProteinP03372 (Uniprot-TrEMBL)
ESR1:ESTGComplexR-HSA-1254381 (Reactome)
ESTG MetaboliteCHEBI:50114 (ChEBI)
GABA MetaboliteCHEBI:59888 (ChEBI)
GABRA1 heteropentamers:GABAComplexR-HSA-9612613 (Reactome)
GABRA1 ProteinP14867 (Uniprot-TrEMBL)
GABRB1 ProteinP18505 (Uniprot-TrEMBL)
GABRB2 ProteinP47870 (Uniprot-TrEMBL)
GABRB3 ProteinP28472 (Uniprot-TrEMBL)
GABRG2 ProteinP18507 (Uniprot-TrEMBL)
GABRG3 ProteinQ99928 (Uniprot-TrEMBL)
GABRQ ProteinQ9UN88 (Uniprot-TrEMBL)
GDP MetaboliteCHEBI:17552 (ChEBI)
GDPMetaboliteCHEBI:17552 (ChEBI)
GFAP gene ProteinENSG00000131095 (Ensembl)
GFAP geneGeneProductENSG00000131095 (Ensembl)
GFAPProteinP14136 (Uniprot-TrEMBL)
GRB2-1 ProteinP62993-1 (Uniprot-TrEMBL)
GRB2-1:SOS1ComplexR-HSA-109797 (Reactome)
GRB2:SOS1:p-Y349,350-SHC1:p-ERBB4ComplexR-HSA-1250382 (Reactome)
GTP MetaboliteCHEBI:15996 (ChEBI)
GTPMetaboliteCHEBI:15996 (ChEBI)
ITCH ProteinQ96J02 (Uniprot-TrEMBL)
MXD4 gene ProteinENSG00000123933 (Ensembl)
MXD4 geneGeneProductENSG00000123933 (Ensembl)
MXD4ProteinQ14582 (Uniprot-TrEMBL)
MyrG-p-Y419-SRC ProteinP12931 (Uniprot-TrEMBL)
MyrG-p-Y419-SRCProteinP12931 (Uniprot-TrEMBL)
NCOR1 ProteinO75376 (Uniprot-TrEMBL)
NCSTN ProteinQ92542 (Uniprot-TrEMBL)
NEDD4 ProteinP46934 (Uniprot-TrEMBL)
NEDD4ProteinP46934 (Uniprot-TrEMBL)
NRG1 R-HSA-1233225 (Reactome)
NRG1/2:ERBB3ComplexR-HSA-1247495 (Reactome)
NRG2 ProteinO14511 (Uniprot-TrEMBL)
NRG2:p-ERBB4

homodimers:GABRA1

heteropentamers:GABA
ComplexR-HSA-9612640 (Reactome)
NRG2:p-ERBB4 homodimersComplexR-HSA-9612622 (Reactome)
NRG2:p-ERBB4cyt1 homodimers R-HSA-9612624 (Reactome)
NRGs/EGF-like ligands:ERBB4ComplexR-HSA-1236393 (Reactome)
NRGs/EGF-like ligandsComplexR-HSA-1233236 (Reactome)
Neuregulins R-HSA-1227957 (Reactome)
PGR gene ProteinENSG00000082175 (Ensembl)
PGR geneGeneProductENSG00000082175 (Ensembl)
PGRProteinP06401 (Uniprot-TrEMBL)
PI(3,4,5)P3MetaboliteCHEBI:16618 (ChEBI)
PI(4,5)P2MetaboliteCHEBI:18348 (ChEBI)
PI3K:p-ERBB4cyt1ComplexR-HSA-1250373 (Reactome)
PIK3CA ProteinP42336 (Uniprot-TrEMBL)
PIK3CA:PIK3R1ComplexR-HSA-1806218 (Reactome)
PIK3R1 ProteinP27986 (Uniprot-TrEMBL)
PIP3 activates AKT signalingPathwayR-HSA-1257604 (Reactome) Signaling by AKT is one of the key outcomes of receptor tyrosine kinase (RTK) activation. AKT is activated by the cellular second messenger PIP3, a phospholipid that is generated by PI3K. In ustimulated cells, PI3K class IA enzymes reside in the cytosol as inactive heterodimers composed of p85 regulatory subunit and p110 catalytic subunit. In this complex, p85 stabilizes p110 while inhibiting its catalytic activity. Upon binding of extracellular ligands to RTKs, receptors dimerize and undergo autophosphorylation. The regulatory subunit of PI3K, p85, is recruited to phosphorylated cytosolic RTK domains either directly or indirectly, through adaptor proteins, leading to a conformational change in the PI3K IA heterodimer that relieves inhibition of the p110 catalytic subunit. Activated PI3K IA phosphorylates PIP2, converting it to PIP3; this reaction is negatively regulated by PTEN phosphatase. PIP3 recruits AKT to the plasma membrane, allowing TORC2 to phosphorylate a conserved serine residue of AKT. Phosphorylation of this serine induces a conformation change in AKT, exposing a conserved threonine residue that is then phosphorylated by PDPK1 (PDK1). Phosphorylation of both the threonine and the serine residue is required to fully activate AKT. The active AKT then dissociates from PIP3 and phosphorylates a number of cytosolic and nuclear proteins that play important roles in cell survival and metabolism. For a recent review of AKT signaling, please refer to Manning and Cantley, 2007.
PSEN1(1-298) ProteinP49768 (Uniprot-TrEMBL)
PSEN1(299-467) ProteinP49768 (Uniprot-TrEMBL)
PSEN2(1-297) ProteinP49810 (Uniprot-TrEMBL)
PSEN2(298-448) ProteinP49810 (Uniprot-TrEMBL)
PSENEN ProteinQ9NZ42 (Uniprot-TrEMBL)
Prolactin receptor signalingPathwayR-HSA-1170546 (Reactome) Prolactin (PRL) is a hormone secreted mainly by the anterior pituitary gland. It was originally identified by its ability to stimulate the development of the mammary gland and lactation, but is now known to have numerous and varied functions (Bole-Feysot et al. 1998). Despite this, few pathologies have been associated with abnormalities in prolactin receptor (PRLR) signaling, though roles in various forms of cancer and certain autoimmune disorders have been suggested (Goffin et al. 2002). A vast body of literature suggests effects of PRL in immune cells (Matera 1996) but PRLR KO mice have unaltered immune system development and function (Bouchard et al. 1999). In addition to the pituitary, numerous other tissues produce PRL, including the decidua and myometrium, certain cells of the immune system, brain, skin and exocrine glands such as the mammary, sweat and lacrimal glands (Ben-Jonathan et al. 1996). Pituitary PRL secretion is negatively regulated by inhibitory factors originating from the hypothalamus, the most important of which is dopamine, acting through the D2 subclass of dopamine receptors present in lactotrophs (Freeman et al. 2000). PRL-binding sites or receptors have been identified in numerous cells and tissues of adult mammals. Various forms of PRLR, generated by alternative splicing, have been reported in several species including humans (Kelly et al. 1991, Clevenger et al. 2003).

PRLR is a member of the cytokine receptor superfamily. Like many other members of this family, the first step in receptor activation was generally believed to be ligand-induced dimerization whereby one molecule of PRL bound to two molecules of receptor (Elkins et al. 2000). Recent reports suggest that PRLR pre-assembles at the plasma membrane in the absence of ligand (Gadd & Clevenger 2006, Tallet et al. 2011), suggesting that ligand-induced activation involves conformational changes in preformed PRLR dimers (Broutin et al. 2010).

PRLR has no intrinsic kinase activity but associates (Lebrun et al. 1994, 1995) with Janus kinase 2 (JAK2) which is activated following receptor activation (Campbell et al. 1994, Rui et al. 1994, Carter-Su et al. 2000, Barua et al. 2009). JAK2-dependent activation of JAK1 has also been reported (Neilson et al. 2007). It is generally accepted that activation of JAK2 occurs by transphosphorylation upon ligand-induced receptor activation, based on JAK activation by chimeric receptors in which various extracellular domains of cytokine or tyrosine kinase receptors were fused to the IL-2 receptor beta chain (see Ihle et al. 1994). This activation step involves the tyrosine phosphorylation of JAK2, which in turn phosphorylates PRLR on specific intracellular tyrosine residues leading to STAT5 recruitment and signaling, considered to be the most important signaling cascade for PRLR. STAT1 and STAT3 activation have also been reported (DaSilva et al. 1996) as have many other signaling pathways; signaling through MAP kinases (Shc/SOS/Grb2/Ras/Raf/MAPK) has been reported as a consequence of PRL stimuilation in many different cellular systems (see Bole-Feysot et al. 1998) though it is not clear how this signal is propagated. Other cascades non exhaustively include Src kinases, Focal adhesion kinase, phospholipase C gamma, PI3 kinase/Akt and Nek3 (Clevenger et al. 2003, Miller et al. 2007). The protein tyrosine phosphatase SHP2 is recruited to the C terminal tyrosine of PRLR and may have a regulatory role (Ali & Ali 2000). PRLR phosphotyrosines can recruit insulin receptor substrates (IRS) and other adaptor proteins to the receptor complex (Bole-Feysot et al. 1998).

Female homozygous PRLR knockout mice are completely infertile and show a lack of mammary development (Ormandy et al. 1997). Hemizogotes are unable to lactate following their first pregnancy and depending on the genetic background, this phenotype can persist through subsequent pregnancies (Kelly et al. 2001).
RAF/MAP kinase cascadePathwayR-HSA-5673001 (Reactome) The RAS-RAF-MEK-ERK pathway regulates processes such as proliferation, differentiation, survival, senescence and cell motility in response to growth factors, hormones and cytokines, among others. Binding of these stimuli to receptors in the plasma membrane promotes the GEF-mediated activation of RAS at the plasma membrane and initiates the three-tiered kinase cascade of the conventional MAPK cascades. GTP-bound RAS recruits RAF (the MAPK kinase kinase), and promotes its dimerization and activation (reviewed in Cseh et al, 2014; Roskoski, 2010; McKay and Morrison, 2007; Wellbrock et al, 2004). Activated RAF phosphorylates the MAPK kinase proteins MEK1 and MEK2 (also known as MAP2K1 and MAP2K2), which in turn phophorylate the proline-directed kinases ERK1 and 2 (also known as MAPK3 and MAPK1) (reviewed in Roskoski, 2012a, b; Kryiakis and Avruch, 2012). Activated ERK proteins may undergo dimerization and have identified targets in both the nucleus and the cytosol; consistent with this, a proportion of activated ERK protein relocalizes to the nucleus in response to stimuli (reviewed in Roskoski 2012b; Turjanski et al, 2007; Plotnikov et al, 2010; Cargnello et al, 2011). Although initially seen as a linear cascade originating at the plasma membrane and culminating in the nucleus, the RAS/RAF MAPK cascade is now also known to be activated from various intracellular location. Temporal and spatial specificity of the cascade is achieved in part through the interaction of pathway components with numerous scaffolding proteins (reviewed in McKay and Morrison, 2007; Brown and Sacks, 2009).
The importance of the RAS/RAF MAPK cascade is highlighted by the fact that components of this pathway are mutated with high frequency in a large number of human cancers. Activating mutations in RAS are found in approximately one third of human cancers, while ~8% of tumors express an activated form of BRAF (Roberts and Der, 2007; Davies et al, 2002; Cantwell-Dorris et al, 2011).
RPS27A(1-76) ProteinP62979 (Uniprot-TrEMBL)
S-Farn-Me KRAS4B ProteinP01116-2 (Uniprot-TrEMBL)
S-Farn-Me PalmS NRAS ProteinP01111 (Uniprot-TrEMBL)
S-Farn-Me-2xPalmS HRAS ProteinP01112 (Uniprot-TrEMBL)
S-Farn-Me-PalmS KRAS4A ProteinP01116-1 (Uniprot-TrEMBL)
S100B gene ProteinENSG00000160307 (Ensembl)
S100B geneGeneProductENSG00000160307 (Ensembl)
S100BProteinP04271 (Uniprot-TrEMBL)
SHC1 ProteinP29353 (Uniprot-TrEMBL)
SHC1:p-ERBB4ComplexR-HSA-1250359 (Reactome)
SHC1ProteinP29353 (Uniprot-TrEMBL)
SOS1 ProteinQ07889 (Uniprot-TrEMBL)
SPARC gene ProteinENSG00000113140 (Ensembl)
SPARC geneGeneProductENSG00000113140 (Ensembl)
SPARCProteinP09486 (Uniprot-TrEMBL)
STMN1 gene ProteinENSG00000117632 (Ensembl)
STMN1 geneGeneProductENSG00000117632 (Ensembl)
STMN1ProteinP16949 (Uniprot-TrEMBL)
Signaling by HippoPathwayR-HSA-2028269 (Reactome) Human Hippo signaling is a network of reactions that regulates cell proliferation and apoptosis, centered on a three-step kinase cascade. The cascade was discovered by analysis of Drosophila mutations that lead to tissue overgrowth, and human homologues of its components have since been identified and characterized at a molecular level. Data from studies of mice carrying knockout mutant alleles of the genes as well as from studies of somatic mutations in these genes in human tumors are consistent with the conclusion that in mammals, as in flies, the Hippo cascade is required for normal regulation of cell proliferation and defects in the pathway are associated with cell overgrowth and tumorigenesis (Oh and Irvine 2010; Pan 2010; Zhao et al. 2010). This group of reactions is also notable for its abundance of protein:protein interactions mediated by WW domains and PPxY sequence motifs (Sudol and Harvey 2010).

There are two human homologues of each of the three Drosophila kinases, whose functions are well conserved: expression of human proteins rescues fly mutants. The two members of each pair of human homologues have biochemically indistinguishable functions. Autophosphorylated STK3 (MST2) and STK4 (MST1) (homologues of Drosophila Hippo) catalyze the phosphorylation and activation of LATS1 and LATS2 (homologues of Drosophila Warts) and of the accessory proteins MOB1A and MOB1B (homologues of Drosophila Mats). LATS1 and LATS2 in turn catalyze the phosphorylation of the transcriptional co-activators YAP1 and WWTR1 (TAZ) (homologues of Drosophila Yorkie).

In their unphosphorylated states, YAP1 and WWTR1 freely enter the nucleus and function as transcriptional co-activators. In their phosphorylated states, however, YAP1 and WWTR1 are instead bound by 14-3-3 proteins, YWHAB and YWHAE respectively, and sequestered in the cytosol.

Several accessory proteins are required for the three-step kinase cascade to function. STK3 (MST2) and STK4 (MST1) each form a complex with SAV1 (homologue of Drosophila Salvador), and LATS1 and LATS2 form complexes with MOB1A and MOB1B (homologues of Drosophila Mats).

In Drosophila a complex of three proteins, Kibra, Expanded, and Merlin, can trigger the Hippo cascade. A human homologue of Kibra, WWC1, has been identified and indirect evidence suggests that it can regulate the human Hippo pathway (Xiao et al. 2011). A molecular mechanism for this interaction has not yet been worked out and the molecular steps that trigger the Hippo kinase cascade in humans are unknown.

Four additional processes related to human Hippo signaling, although incompletely characterized, have been described in sufficient detail to allow their annotation. All are of physiological interest as they are likely to be parts of mechanisms by which Hippo signaling is modulated or functionally linked to other signaling processes. First, the caspase 3 protease cleaves STK3 (MST2) and STK4 (MST1), releasing inhibitory carboxyterminal domains in each case, leading to increased kinase activity and YAP1 / TAZ phosphorylation (Lee et al. 2001). Second, cytosolic AMOT (angiomotin) proteins can bind YAP1 and WWTR1 (TAZ) in their unphosphorylated states, a process that may provide a Hippo-independent mechanism to down-regulate the activities of these proteins (Chan et al. 2011). Third, WWTR1 (TAZ) and YAP1 bind ZO-1 and 2 proteins (Remue et al. 2010; Oka et al. 2010). Fourth, phosphorylated WWTR1 (TAZ) binds and sequesters DVL2, providing a molecular link between Hippo and Wnt signaling (Varelas et al. 2010).

TAB2 ProteinQ9NYJ8 (Uniprot-TrEMBL)
TAB2:NCOR1ComplexR-HSA-1253312 (Reactome)
UBA52(1-76) ProteinP62987 (Uniprot-TrEMBL)
UBB(1-76) ProteinP0CG47 (Uniprot-TrEMBL)
UBB(153-228) ProteinP0CG47 (Uniprot-TrEMBL)
UBB(77-152) ProteinP0CG47 (Uniprot-TrEMBL)
UBC(1-76) ProteinP0CG48 (Uniprot-TrEMBL)
UBC(153-228) ProteinP0CG48 (Uniprot-TrEMBL)
UBC(229-304) ProteinP0CG48 (Uniprot-TrEMBL)
UBC(305-380) ProteinP0CG48 (Uniprot-TrEMBL)
UBC(381-456) ProteinP0CG48 (Uniprot-TrEMBL)
UBC(457-532) ProteinP0CG48 (Uniprot-TrEMBL)
UBC(533-608) ProteinP0CG48 (Uniprot-TrEMBL)
UBC(609-684) ProteinP0CG48 (Uniprot-TrEMBL)
UBC(77-152) ProteinP0CG48 (Uniprot-TrEMBL)
Ub-ERBB4:WWP1/ITCHComplexR-HSA-1253293 (Reactome)
Ub-ERBB4jmAcyt1s80:NEDD4ComplexR-HSA-1977297 (Reactome)
UbComplexR-HSA-113595 (Reactome)
WWOX ProteinQ9NZC7 (Uniprot-TrEMBL)
WWOXProteinQ9NZC7 (Uniprot-TrEMBL)
WWP1 ProteinQ9H0M0 (Uniprot-TrEMBL)
WWP1/ITCHComplexR-HSA-1253275 (Reactome)
YAP1 ProteinP46937 (Uniprot-TrEMBL)
YAP1- and WWTR1

(TAZ)-stimulated

gene expression
PathwayR-HSA-2032785 (Reactome) YAP1 and WWTR1 (TAZ) are transcriptional co-activators, both homologues of the Drosophila Yorkie protein. They both interact with members of the TEAD family of transcription factors, and WWTR1 interacts as well with TBX5 and RUNX2, to promote gene expression. Their transcriptional targets include genes critical to regulation of cell proliferation and apoptosis. Their subcellular location is regulated by the Hippo signaling cascade: phosphorylation mediated by this cascade leads to the cytosolic sequestration of both proteins (Murakami et al. 2005; Oh and Irvine 2010).
YAP1ProteinP46937 (Uniprot-TrEMBL)
Zn2+ MetaboliteCHEBI:29105 (ChEBI)
gamma-secretase complexComplexR-HSA-157343 (Reactome)
p-ERBB4 JM-A homodimersComplexR-HSA-1843077 (Reactome)
p-ERBB4 homodimersComplexR-HSA-1250341 (Reactome)
p-ERBB4cyt1 homodimersComplexR-HSA-1250351 (Reactome)
p-ERBB4cyt1 homodimers R-HSA-1250351 (Reactome)
p-Y1046,Y1178,Y1232-ERBB4 JM-B CYT-1 isoform ProteinQ15303-2 (Uniprot-TrEMBL)
p-Y1056,Y1188,Y1242-ERBB4 JM-A CYT-1 isoform ProteinQ15303-1 (Uniprot-TrEMBL)
p-Y1172,Y1226-ERBB4 JM-A CYT-2 isoform ProteinQ15303-3 (Uniprot-TrEMBL)
p-Y349,350-SHC1:p-ERBB4ComplexR-HSA-1250343 (Reactome)
p-Y349,Y350-SHC1 ProteinP29353 (Uniprot-TrEMBL)
p-Y694-STAT5A homodimerComplexR-HSA-507927 (Reactome)
p-Y694-STAT5A ProteinP42229 (Uniprot-TrEMBL)
p21 RAS:GDPComplexR-HSA-109796 (Reactome)
p21 RAS:GTPComplexR-HSA-109783 (Reactome)

Annotated Interactions

View all...
SourceTargetTypeDatabase referenceComment
ADAM17mim-catalysisR-HSA-1251992 (Reactome)
ADAP1 geneR-HSA-9612255 (Reactome)
ADAP1 geneR-HSA-9612257 (Reactome)
ADAP1ArrowR-HSA-9612257 (Reactome)
ADPArrowR-HSA-1250315 (Reactome)
ADPArrowR-HSA-1250348 (Reactome)
ADPArrowR-HSA-1250370 (Reactome)
APOE geneR-HSA-9612243 (Reactome)
APOE geneR-HSA-9612246 (Reactome)
APOEArrowR-HSA-9612243 (Reactome)
ATPR-HSA-1250315 (Reactome)
ATPR-HSA-1250348 (Reactome)
ATPR-HSA-1250370 (Reactome)
CSN2 geneR-HSA-1254290 (Reactome)
CSN2 geneR-HSA-8954224 (Reactome)
CSN2ArrowR-HSA-1254290 (Reactome)
CXCL12 geneR-HSA-8954199 (Reactome)
CXCL12 geneR-HSA-8954207 (Reactome)
CXCL12(22-93)ArrowR-HSA-8954199 (Reactome)
DLG4R-HSA-9612593 (Reactome)
EGF:EGFRR-HSA-1977959 (Reactome)
ERBB4 geneR-HSA-9612671 (Reactome)
ERBB4 geneR-HSA-9612672 (Reactome)
ERBB4 homodimersArrowR-HSA-1250220 (Reactome)
ERBB4 homodimersR-HSA-1250315 (Reactome)
ERBB4 homodimersmim-catalysisR-HSA-1250315 (Reactome)
ERBB4/ERBB4m80/ERBB4s80R-HSA-1253300 (Reactome)
ERBB4/m80/s80:WWP1/ITCHArrowR-HSA-1253300 (Reactome)
ERBB4/m80/s80:WWP1/ITCHR-HSA-1253282 (Reactome)
ERBB4/m80/s80:WWP1/ITCHmim-catalysisR-HSA-1253282 (Reactome)
ERBB4:DLG4ArrowR-HSA-9612593 (Reactome)
ERBB4:EGFR heterodimerArrowR-HSA-1977959 (Reactome)
ERBB4:ERBB3 heterodimerArrowR-HSA-1977958 (Reactome)
ERBB4ArrowR-HSA-9612671 (Reactome)
ERBB4R-HSA-1236398 (Reactome)
ERBB4R-HSA-9612593 (Reactome)
ERBB4_ECDArrowR-HSA-1251992 (Reactome)
ERBB4jmAcyt1s80 dimerR-HSA-1973956 (Reactome)
ERBB4jmAcyt1s80 dimerR-HSA-9612440 (Reactome)
ERBB4jmAcyt1s80:MXD4 geneArrowR-HSA-9612440 (Reactome)
ERBB4jmAcyt1s80:MXD4 geneArrowR-HSA-9612448 (Reactome)
ERBB4jmAcyt1s80:NEDD4ArrowR-HSA-1973956 (Reactome)
ERBB4jmAcyt1s80:NEDD4R-HSA-1977296 (Reactome)
ERBB4jmAcyt1s80:NEDD4mim-catalysisR-HSA-1977296 (Reactome)
ERBB4m80ArrowR-HSA-1251992 (Reactome)
ERBB4m80R-HSA-1251997 (Reactome)
ERBB4s80:ADAP1 geneArrowR-HSA-9612255 (Reactome)
ERBB4s80:ADAP1 geneTBarR-HSA-9612257 (Reactome)
ERBB4s80:APOE geneArrowR-HSA-9612243 (Reactome)
ERBB4s80:APOE geneArrowR-HSA-9612246 (Reactome)
ERBB4s80:ESR1:estrogen:CXCL12 geneArrowR-HSA-8954199 (Reactome)
ERBB4s80:ESR1:estrogen:CXCL12 geneArrowR-HSA-8954207 (Reactome)
ERBB4s80:ESR1:estrogen:ERBB4 geneArrowR-HSA-9612671 (Reactome)
ERBB4s80:ESR1:estrogen:ERBB4 geneArrowR-HSA-9612672 (Reactome)
ERBB4s80:ESR1:estrogen:PGR geneArrowR-HSA-1254392 (Reactome)
ERBB4s80:ESR1:estrogen:PGR geneArrowR-HSA-8954208 (Reactome)
ERBB4s80:ESR1:estrogenArrowR-HSA-1254386 (Reactome)
ERBB4s80:ESR1:estrogenR-HSA-8954207 (Reactome)
ERBB4s80:ESR1:estrogenR-HSA-8954208 (Reactome)
ERBB4s80:ESR1:estrogenR-HSA-9612672 (Reactome)
ERBB4s80:MyrG-p-Y419-SRCArrowR-HSA-9612219 (Reactome)
ERBB4s80:MyrG-p-Y419-SRCTBarR-HSA-1252013 (Reactome)
ERBB4s80:SPARC geneArrowR-HSA-9612277 (Reactome)
ERBB4s80:SPARC geneArrowR-HSA-9612278 (Reactome)
ERBB4s80:STMN1 geneArrowR-HSA-9612444 (Reactome)
ERBB4s80:STMN1 geneArrowR-HSA-9612445 (Reactome)
ERBB4s80:TAB2:NCOR1:GFAP geneArrowR-HSA-8954185 (Reactome)
ERBB4s80:TAB2:NCOR1:GFAP geneTBarR-HSA-1253321 (Reactome)
ERBB4s80:TAB2:NCOR1:S100B geneArrowR-HSA-8954182 (Reactome)
ERBB4s80:TAB2:NCOR1:S100B geneTBarR-HSA-8954179 (Reactome)
ERBB4s80:TAB2:NCOR1ArrowR-HSA-1253319 (Reactome)
ERBB4s80:TAB2:NCOR1ArrowR-HSA-1253325 (Reactome)
ERBB4s80:TAB2:NCOR1R-HSA-1253319 (Reactome)
ERBB4s80:TAB2:NCOR1R-HSA-8954182 (Reactome)
ERBB4s80:TAB2:NCOR1R-HSA-8954185 (Reactome)
ERBB4s80:WWOXArrowR-HSA-1253343 (Reactome)
ERBB4s80:YAP1ArrowR-HSA-1254248 (Reactome)
ERBB4s80:YAP1ArrowR-HSA-1254251 (Reactome)
ERBB4s80:YAP1R-HSA-1254248 (Reactome)
ERBB4s80:p-Y694-STAT5A:CSN2 geneArrowR-HSA-1254290 (Reactome)
ERBB4s80:p-Y694-STAT5A:CSN2 geneArrowR-HSA-8954224 (Reactome)
ERBB4s80:p-Y694-STAT5AArrowR-HSA-1254285 (Reactome)
ERBB4s80:p-Y694-STAT5AArrowR-HSA-1254291 (Reactome)
ERBB4s80:p-Y694-STAT5AR-HSA-1254285 (Reactome)
ERBB4s80:p-Y694-STAT5AR-HSA-8954224 (Reactome)
ERBB4s80ArrowR-HSA-1251997 (Reactome)
ERBB4s80ArrowR-HSA-1252013 (Reactome)
ERBB4s80ArrowR-HSA-1254376 (Reactome)
ERBB4s80R-HSA-1252013 (Reactome)
ERBB4s80R-HSA-1253325 (Reactome)
ERBB4s80R-HSA-1253343 (Reactome)
ERBB4s80R-HSA-1254251 (Reactome)
ERBB4s80R-HSA-1254291 (Reactome)
ERBB4s80R-HSA-1254376 (Reactome)
ERBB4s80R-HSA-1254386 (Reactome)
ERBB4s80R-HSA-9612219 (Reactome)
ERBB4s80R-HSA-9612246 (Reactome)
ERBB4s80R-HSA-9612255 (Reactome)
ERBB4s80R-HSA-9612278 (Reactome)
ERBB4s80R-HSA-9612444 (Reactome)
ESR1:ESTGR-HSA-1254386 (Reactome)
GABRA1 heteropentamers:GABAR-HSA-9612639 (Reactome)
GDPArrowR-HSA-1250383 (Reactome)
GFAP geneR-HSA-1253321 (Reactome)
GFAP geneR-HSA-8954185 (Reactome)
GFAPArrowR-HSA-1253321 (Reactome)
GRB2-1:SOS1R-HSA-1250380 (Reactome)
GRB2:SOS1:p-Y349,350-SHC1:p-ERBB4ArrowR-HSA-1250380 (Reactome)
GRB2:SOS1:p-Y349,350-SHC1:p-ERBB4mim-catalysisR-HSA-1250383 (Reactome)
GTPR-HSA-1250383 (Reactome)
MXD4 geneR-HSA-9612440 (Reactome)
MXD4 geneR-HSA-9612448 (Reactome)
MXD4ArrowR-HSA-9612448 (Reactome)
MyrG-p-Y419-SRCR-HSA-9612219 (Reactome)
NEDD4R-HSA-1973956 (Reactome)
NRG1/2:ERBB3R-HSA-1977958 (Reactome)
NRG2:p-ERBB4

homodimers:GABRA1

heteropentamers:GABA
ArrowR-HSA-9612639 (Reactome)
NRG2:p-ERBB4 homodimersR-HSA-9612639 (Reactome)
NRGs/EGF-like ligands:ERBB4ArrowR-HSA-1236398 (Reactome)
NRGs/EGF-like ligands:ERBB4R-HSA-1250220 (Reactome)
NRGs/EGF-like ligands:ERBB4R-HSA-1977958 (Reactome)
NRGs/EGF-like ligands:ERBB4R-HSA-1977959 (Reactome)
NRGs/EGF-like ligandsR-HSA-1236398 (Reactome)
PGR geneR-HSA-1254392 (Reactome)
PGR geneR-HSA-8954208 (Reactome)
PGRArrowR-HSA-1254392 (Reactome)
PI(3,4,5)P3ArrowR-HSA-1250370 (Reactome)
PI(4,5)P2R-HSA-1250370 (Reactome)
PI3K:p-ERBB4cyt1ArrowR-HSA-1250353 (Reactome)
PI3K:p-ERBB4cyt1mim-catalysisR-HSA-1250370 (Reactome)
PIK3CA:PIK3R1R-HSA-1250353 (Reactome)
R-HSA-1236398 (Reactome) All three ERBB4 isoforms are activated by binding of neuregulins (NRG1, NRG2, NRG3 and NRG4) or EGF like growth factors (betacellulin, epiregulin, HB EGF) to their extracellular domain (Tzahar et al. 1994, Riese et al. 1995, Carraway et al. 1997, Elenius et al. 1997, Zhang et al. 1997, Riese et al. 1998, Hayes et al. 2007).
R-HSA-1250220 (Reactome) Ligand stimulated ERBB4 forms homodimers (Sweeney et al. 2000).
R-HSA-1250315 (Reactome) Homodimers of ERBB4 CYT 1 isoforms trans autophosphorylate on six tyrosine residues (three on each monomer) that serve as docking sites for SHC1 (tyrosines Y1188 and 1242 in the isoform ERBB4 JM-A CYT1; tyrosines Y1178 and Y1232 in the isoform ERBB4 JM-B CYT1) and the p85 subunit of PI3K (tyrosine Y1056 in the isoform ERBB4 JM-A CYT1; tyrosine Y1046 in the isoform ERBB4 JM-B CYT1), while ERBB4 CYT2 isoform homodimer trans-autophosphorylates on four SHC1 binding tyrosines (two on each monomer - tyrosines Y1172 and Y1226) (Cohen et al. 1996, Kaushansky et al. 2008).
NRG1-mediated activation of ERBB4 signaling negatively regulates, via an unknown mechanism, phosphorylation of NMDA receptors by SRC. ERBB4 signaling is hyperactivated in schizophrenia, while SRC-mediated phosphorylation of NMDA receptors (NMDARs) is reduced in schizophrenia. (Pitcher et al. 2011, Banerjee et al. 2015).
R-HSA-1250348 (Reactome) After binding ERBB4 homodimers, SHC1 gets phosphorylated on tyrosine residues Y349 and Y350 (Kainulainen et al. 2000).
R-HSA-1250353 (Reactome) p85 subunit of PI3K (PIK3R1) directly binds to phosphorylated ERBB4 CYT1 homodimers through docking tyrosine residues on either ERBB4 JM A CYT1 (tyrosine Y1056) or ERBB4 JM B CYT1 (tyrosine Y1046) isoform (Cohen et al. 1996, Kainulainen et al. 2000, Kaushansky et al. 2008).
R-HSA-1250357 (Reactome) Phosphorylated tyrosine residues in the C-tail of phosphorylated ERBB4 isoform dimers P-ERBB4jmAcyt1, P-ERBB4jmAcyt2 and P-ERBB4jmBcyt1 recruit SHC1 (Cohen et al. 1996, Pinkas-Kramarski et al. 1996, Kaushansky et al. 2008).
R-HSA-1250370 (Reactome) Activated PI3K bound to phosphorylated ERBB4 CYT-1 homodimers converts PIP2 into PIP3, which leads to activation of AKT signaling (Kainulainen et al. 2000).
R-HSA-1250380 (Reactome) Phosphorylated SHC1 bound to phosphorylated ERBB4 homodimers recruits GRB2:SOS1 complex (Kainulainen et al. 2000).
R-HSA-1250383 (Reactome) SOS1 in complex with GRB2 and p-Y349,350-SHC1:p-ERBB4 activates RAS by mediating guanyl nucleotide exchange, which results in the activation of RAF/MAP kinase cascade (Kainulainen et al. 2000).
R-HSA-1251992 (Reactome) Phosphorylated ligand-bound homodimers of ERBB4 JM-A isoforms are cleaved by ADAM17 metalloproteinase to yield ligand-bound ERBB4 extracellular domain and membrane bound ERBB4 fragment of 80 kDa (ERBB4m80) (Rio et al. 2000, Cheng et al. 2003).
R-HSA-1251997 (Reactome) After ERBB4 is cleaved by ADAM17, gamma-secretase complex performs additional cleavage in the transmembrane region of the m80 ERBB4 fragment, releasing the soluble ERBB4 intracellular domain of 80 kDa, known as s80 or E4ICD (Ni et al. 2001).
R-HSA-1252013 (Reactome) The soluble intracellular domain of ERBB4 s80 (E4ICD) is able to translocate from the cytosol to the nucleus (Ni et al. 2001). Translocation of ERBB4s80 to the nucleus is negatively regulated by binding of ERBB4s80 to activated SRC kinase (Ishibashi et al. 2012).
R-HSA-1253282 (Reactome) Upon binding to ERBB4 or its cleavage products m80 and s80, NEDD4 family ligases WWP1 and ITCH ubiquitinate intact and cleaved ERBB4 and target it for degradation (Omerovic et al. 2007, Feng et al. 2009).
R-HSA-1253300 (Reactome) Intact ERBB4 isoforms and their membrane bound and cytosolic cleavage products, m80 and s80, bind NEDD4 family E3 ubiquitin ligases WWP1 and ITCH through WW-binding motifs in the C-tail. This interaction is independent of ligand binding and ERBB4 phosphorylation. CYT1 isoforms of ERBB4 have three WW-binding motifs: PY1, PY2 and PY3. PY2 motif is unique to CYT1 isoforms and overlaps with the PIK3R1 binding site. CYT2 isoform of ERBB4 has two WW-binding motifs: PY1 and PY3. While both CYT1 and CYT2 isoforms of ERBB4 all bind WWP1, CYT1 intracellular domain exhibits higher affinity for WWP1. Based on co-immunoprecipitation experiments in which individual WW-binding motifs of ERBB4 were mutated, Feng et al. established that PY2 had the highest affinity for WWP1, followed by PY3, while PY1 showed the lowest affinity (Omerovic et al. 2007, Feng et al. 2009).
R-HSA-1253319 (Reactome) ERBB4s80 (E4ICD) bound to cytosolic TAB2:NCOR1 complex mediates the translocation of this complex to the nucleus (Sardi et al. 2006).
R-HSA-1253321 (Reactome) Transcription of the GFAP gene, involved in astrocyte differentiation, is inhibited by binding of the ERBB4s80:TAB2:NCOR1 complex to the GFAP promoter (Sardi et al. 2006).
R-HSA-1253325 (Reactome) ERBB4s80 (E4ICD) binds cytosolic TAB2:NCOR1 complex through direct interaction with TAB2 (Sardi et al. 2006).
R-HSA-1253343 (Reactome) WWOX binds to ERBB4s80 through WW-domain binding motifs in the C-tail of ERBB4. Formation of ERBB4s80:WWOX complex competes with the formation of ERBB4:YAP1 complex and prevents translocation of ERBB4s80 to the nucleus. Feng et al. established that WWOX binds with the same affinity to s80CYT1 and s80CYT2, and identified PY3 as the most important WW-domain binding motif for WWOX binding (Aqeilan et al. 2005, Feng et al. 2009, Schuchardt et al. 2013).
R-HSA-1254248 (Reactome) Upon formation of ERBB4s80:YAP1 complex in the cytosol, the complex translocates to the nucleus, where it may act as a regulator of transcription (Komuro et al. 2003, Omerovic et al. 2004, Aqeilan et al. 2005).
R-HSA-1254251 (Reactome) ERBB4s80 interacts with a co-transcriptional activator YAP1 through its WW-domain binding motifs in the C-tail. Feng et al. established that the PY2 motif, present in CYT1 isoforms of ERBB4 only, has the highest affinity for YAP1 binding. PY1 and PY3 motifs, shared between CYT1 and CYT2 isoforms, have lower binding affinity for YAP1, with PY1 motif being the least important for YAP1 interaction (Komuro et al. 2003, Omerovic et al. 2004, Feng et al. 2009).
R-HSA-1254285 (Reactome) Formation of cytosolic complex of ERBB4s80 and STAT5A promotes translocation of STAT5A to the nucleus, with ERBB4s80 acting as a nuclear chaperone of STAT5A.
R-HSA-1254290 (Reactome) ERBB4s80:STAT5A complex binds to and stimulates transcription from the beta-casein (CSN2) promoter, and it probably regulates transcription of other lactation-related genes in mammary cells. By over-expressing either human ERBB4cyt1s80 or ERBB4cyt2s80 in mouse mammary cell line HC11 or transgenic mice, Muraoka-Cook et al. showed differential effects of CYT1 and CYT2 isoforms on mammary epithelium. CYT1s80 over-expression decreases cell proliferation, promotes STAT5A-mediated transcription of beta-casein (CSN2) and lactogenic differentiation. In contrast, CYT2s80 over-expression causes epithelial hyperplasia, increased levels of Wnt and beta-catenin, as well as elevated expression of c-myc and cyclin D1 (Muraoka-Cook et al. 2009).
R-HSA-1254291 (Reactome) ERBB4s80 binds STAT5A through STAT5A SH2 domain. This interaction likely depends on STAT5A activation induced by prolactin and mediated by JAK2. Heterodimers of prolactin receptor (PRLR) and JAK2 are activated by prolactin binding, resulting in STAT5 recruitment and phosphorylation, and subsequent formation of phosphorylated STAT5 homodimers. There is evidence that ERBB4 may be part of the PRLR:JAK2 complex and that it may be activated by JAK2-mediated phosphorylation, in the absence of ERBB4 growth factors (Muraoka-Cook et al. 2008).
R-HSA-1254376 (Reactome) Cytosolic ERBB4s80 is able to translocate to mitochondria where its BH3 domain, characteristic of BCL2 family members, may enable it to act as a pro-apoptotic factor (Naresh et al. 2006).
R-HSA-1254386 (Reactome) ERBB4s80 forms a complex with activated estrogen receptor ESR1 in the nucleus and acts as a transcriptional co-factor for ESR1 (Zhu et al. 2006).
R-HSA-1254392 (Reactome) The complex of ERBB4s80 and activated estrogen receptor ESR1 promotes transcription of the PGR gene, encoding progesterone receptor (Zhu et al. 2006).
R-HSA-1973956 (Reactome) E3 ubiquitin ligase NEDD4 binds intracellular domain of ERBB4 isoform JM-A CYT1 (ERBB4jmAcyt1s80) produced by ERBB4 cleavage (Zeng et al. 2009).
R-HSA-1977296 (Reactome) E3 ubiquitin ligase NEDD4 mediates ubiquitination of ERBB4 JM-A CYT-1 intracellular domain s80 (ERBB4jmAcyt1s80) produced by ERBB4 cleavage. This induces degradation of ERBB4jmAcyt1s80, and decreases the amount of ERBB4jmAcyt1s80 that reaches the nucleus (Zeng et al. 2009).
R-HSA-1977958 (Reactome) Ligand-stimulated ERBB4 was shown to form heterodimers with ligand-stimulated ERBB3 when human ERBB4 and ERBB3 were exogenously expressed in mouse pro-B-lymphocyte cell line. Heterodimers of ERBB4 and ERBB3 undergo trans-autophosphorylation, but the exact phosphorylation pattern, downstream signaling and physiological significance of these heterodimers have not been studied (Riese et al. 1995).
R-HSA-1977959 (Reactome) Ligand-stimulated ERBB4 was shown to form heterodimers with ligand-stimulated EGFR when human ERBB4 and EGFR were exogenously expressed in mouse fibroblast cell line. Heterodimers of ERBB4 and EGFR undergo trans-autophosphorylation, but the exact phosphorylation pattern, downstream signaling and physiological significance of these heterodimers have not been studied (Riese et al. 1995, Cohen et al. 1996). Binding of ERBB4 CYT2 isoform to EGFR protects EGFR from ligand-induced degradation by preventing binding of the CBL:GRB2 complex to EGFR (Kiuchi et al. 2014).
R-HSA-8954179 (Reactome) Transcription of the S100B gene, involved in astrocyte differentiation, is inhibited by binding of the ERBB4s80:TAB2:NCOR1 complex to the S100B promoter (Sardi et al. 2006).
R-HSA-8954182 (Reactome) The ERBB4s80:TAB2:NCOR1 complex binds the promoter of the S100B gene (Sardi et al. 2006).
R-HSA-8954185 (Reactome) The ERBB4s80:TAB2:NCOR1 complex binds the promoter of the GFAP gene (Sardi et al. 2006).
R-HSA-8954199 (Reactome) The complex of ERBB4s80 and activated estrogen receptor ESR1 promotes transcription of the CXCL12 gene, encoding Stromal cell-derived factor 1 (SDF1) (Zhu et al. 2006).
R-HSA-8954207 (Reactome) The complex of ERBB4s80 and activated estrogen receptor ESR1 binds estrogen response elements (EREs) in the promoter of the CXCL12 gene, encoding Stromal cell-derived factor 1 (Zhu et al. 2006).
R-HSA-8954208 (Reactome) The complex of ERBB4s80 and activated estrogen receptor ESR1 binds estrogen response elements (EREs) in the promoter of the PGR (NR3C3) gene, encoding Progesterone receptor (Zhu et al. 2006).
R-HSA-8954224 (Reactome) ERBB4s80:STAT5A complex binds to the promoter of the CSN2 gene, encoding beta-casein (Williams et al. 2004, Muraoka-Cook et al. 2008).
R-HSA-9612219 (Reactome) SRC tyrosine kinase, activated by EGFR signaling, binds to the cleaved intracellular fragment of ERBB4, ERBB4s80 (E4ICD), released in response to ERBB4 activation by NRG1. Tyrosine phosphorylation of ERBB4s80 is needed for SRC binding. It is not clear whether tyrosine phosphorylation sites are auto-phosphorylated or phosphorylated by SRC. SRC binding prevents translocation of ERBB4s80 to the nucleus (Ishibashi et al. 2012).
R-HSA-9612243 (Reactome) Transcription of the APOE gene, encoding Apolipoprotein E, involved in binding and internalization of lipoprotein particles, is stimulated by the intracellular fragment of ERBB4, ERBB4s80 (E4ICD) (Wali et al. 2014).
R-HSA-9612246 (Reactome) The intracellular fragment of ERBB4, ERBB4s80 (E4ICD) binds to the promoter region of the APOE gene, about 2 kb upstream from the transcription start site. The ERBB4s80 binding site overlaps with HNF4 and ETS1 binding sites (Wali et al. 2014).
R-HSA-9612255 (Reactome) The intracellular fragment of ERBB4, ERBB4s80 (E4ICD) binds to the promoter region of the ADAP1 gene, about 3-4 kb upstream of the transcription start site. The ERBB4s80 binding site overlaps with a CEBPB binding site (Wali et al. 2014).
R-HSA-9612257 (Reactome) The intracellular fragment of ERBB4, ERBB4s80 (E4ICD) inhibits transcription of the ADAP1 gene, encoding Arf-GAP with dual PH domain-containing protein 1 (also known as CENTA1 or Centaurin-alpha-1).
R-HSA-9612277 (Reactome) The intracellular fragment of ERBB4, ERBB4s80 (E4ICD) stimulates transcription of the SPARC gene, encoding Basement-membrane protein 40 (BM-40) (Wali et al. 2014).
R-HSA-9612278 (Reactome) The intracellular fragment of ERBB4, ERBB4s80 (E4ICD), binds to the promoter region of the SPARC gene. The ERBB4s80 binding site overlaps with binding elements for BRACH, ATF6, ATF and XBP1 transcription factors (Wali et al. 2014).
R-HSA-9612440 (Reactome) The intracellular fragment of the cyt1 isoform of ERBB4, ERBB4jmAcyt1s80, binds the promoter region of the MXD4 gene. The ERBB4 binding site overlaps with MYC and CTCF binding elements (Wali et al. 2014).
R-HSA-9612444 (Reactome) The intracellular fragment of ERBB4, ERBB4s80 (E4ICD) binds the promoter region of the STMN1 gene. The ERBB4s80 binding site overlaps with the TCF4 response element (Wali et al. 2014).
R-HSA-9612445 (Reactome) The intracellular fragment of ERBB4, ERBB4s80 (E4ICD), stimulates transcription of the STMN1 gene, encoding the cytoskeleton-associated protein, Stathmin (Wali et al. 2014).
R-HSA-9612448 (Reactome) The intracellular fragment of the cyt1 isoform of ERBB4, ERBB4jmAcyt1s80, stimulates transcription of the MXD4 gene, encoding MAD-binding protein MXD4, which is thought to compete with MYC for MAD binding and thus interferes with MYC-mediated transcription (Wali et al. 2014).
R-HSA-9612593 (Reactome) ERBB4 can bind to a postsynaptic density (PSD) protein DLG4 (PSD-95) (Huang et al. 2000, Garcia et al. 2000). Binding to DLG4 enables ERBB4 to localize to the PSD, where it can modulate the activity of neurotransmitter receptors, but most ERBB4 receptors are found outside of the PSD in neuronal cells (Mitchell et al. 2013). One molecule of DLG4 can bind two molecules of ERBB4, which may facilitate ERBB4 dimerization upon ligand binding (Huang et al. 2000).
R-HSA-9612639 (Reactome) NRG2-activated ERBB4 receptor binds to GABA receptors by directly interacting with the GABRA1 (GABA receptor alpha1) subunit. ERBB4 kinase activity is not necessary for interaction with GABRA1. ERBB4 binding reduces currents through the GABA receptor channel by promoting GABA receptor clearance from the postsynaptic membrane via clathrin-dependent endocytosis (Mitchell et al. 2013). The mechanism of endocytosis of GABRA1-containing GABA receptors via NRG2-bound ERBB4 is not known.
R-HSA-9612671 (Reactome) The complex of intracellular fragment of ERBB4, ERBB4s80 (E4ICD) and activated estrogen receptor (ESR1:estrogen) stimulates transcription of the ERBB4 gene (Zhu et al. 2006).
R-HSA-9612672 (Reactome) The complex of intracellular ERBB4 fragment, ERBB4s80 (E4ICD), and activated estrogen receptor (ESR1:estrogen), binds to estrogen-response elements in the promoter of the ERBB4 gene (Zhu et al. 2006).
S100B geneR-HSA-8954179 (Reactome)
S100B geneR-HSA-8954182 (Reactome)
S100BArrowR-HSA-8954179 (Reactome)
SHC1:p-ERBB4ArrowR-HSA-1250357 (Reactome)
SHC1:p-ERBB4R-HSA-1250348 (Reactome)
SHC1:p-ERBB4mim-catalysisR-HSA-1250348 (Reactome)
SHC1R-HSA-1250357 (Reactome)
SPARC geneR-HSA-9612277 (Reactome)
SPARC geneR-HSA-9612278 (Reactome)
SPARCArrowR-HSA-9612277 (Reactome)
STMN1 geneR-HSA-9612444 (Reactome)
STMN1 geneR-HSA-9612445 (Reactome)
STMN1ArrowR-HSA-9612445 (Reactome)
TAB2:NCOR1R-HSA-1253325 (Reactome)
Ub-ERBB4:WWP1/ITCHArrowR-HSA-1253282 (Reactome)
Ub-ERBB4jmAcyt1s80:NEDD4ArrowR-HSA-1977296 (Reactome)
UbR-HSA-1253282 (Reactome)
UbR-HSA-1977296 (Reactome)
WWOXR-HSA-1253343 (Reactome)
WWP1/ITCHR-HSA-1253300 (Reactome)
YAP1R-HSA-1254251 (Reactome)
gamma-secretase complexmim-catalysisR-HSA-1251997 (Reactome)
p-ERBB4 JM-A homodimersR-HSA-1251992 (Reactome)
p-ERBB4 homodimersArrowR-HSA-1250315 (Reactome)
p-ERBB4 homodimersR-HSA-1250357 (Reactome)
p-ERBB4cyt1 homodimersR-HSA-1250353 (Reactome)
p-Y349,350-SHC1:p-ERBB4ArrowR-HSA-1250348 (Reactome)
p-Y349,350-SHC1:p-ERBB4R-HSA-1250380 (Reactome)
p-Y694-STAT5A homodimerR-HSA-1254291 (Reactome)
p21 RAS:GDPR-HSA-1250383 (Reactome)
p21 RAS:GTPArrowR-HSA-1250383 (Reactome)
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