RET signaling (Homo sapiens)

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Bibliography

1. Borrello MG, Alberti L, Arighi E, Bongarzone I, Battistini C, Bardelli A, Pasini B, Piutti C, Rizzetti MG, Mondellini P, Radice MT, Pierotti MA.; ''The full oncogenic activity of Ret/ptc2 depends on tyrosine 539, a docking site for phospholipase Cgamma.''; PubMed Europe PMC Scholia
2. McKay MM, Morrison DK.; ''Integrating signals from RTKs to ERK/MAPK.''; PubMed Europe PMC Scholia
3. Hennige AM, Lammers R, Arlt D, Höppner W, Strack V, Niederfellner G, Seif FJ, Häring HU, Kellerer M.; ''Ret oncogene signal transduction via a IRS-2/PI 3-kinase/PKB and a SHC/Grb-2 dependent pathway: possible implication for transforming activity in NIH3T3 cells.''; PubMed Europe PMC Scholia
4. Arighi E, Alberti L, Torriti F, Ghizzoni S, Rizzetti MG, Pelicci G, Pasini B, Bongarzone I, Piutti C, Pierotti MA, Borrello MG.; ''Identification of Shc docking site on Ret tyrosine kinase.''; PubMed Europe PMC Scholia
5. Cargnello M, Roux PP.; ''Activation and function of the MAPKs and their substrates, the MAPK-activated protein kinases.''; PubMed Europe PMC Scholia
6. Schuetz G, Rosário M, Grimm J, Boeckers TM, Gundelfinger ED, Birchmeier W.; ''The neuronal scaffold protein Shank3 mediates signaling and biological function of the receptor tyrosine kinase Ret in epithelial cells.''; PubMed Europe PMC Scholia
7. Murakumo Y, Jijiwa M, Asai N, Ichihara M, Takahashi M.; ''RET and neuroendocrine tumors.''; PubMed Europe PMC Scholia
8. Wellbrock C, Karasarides M, Marais R.; ''The RAF proteins take centre stage.''; PubMed Europe PMC Scholia
9. Kurokawa K, Iwashita T, Murakami H, Hayashi H, Kawai K, Takahashi M.; ''Identification of SNT/FRS2 docking site on RET receptor tyrosine kinase and its role for signal transduction.''; PubMed Europe PMC Scholia
10. Fantin VR, Sparling JD, Slot JW, Keller SR, Lienhard GE, Lavan BE.; ''Characterization of insulin receptor substrate 4 in human embryonic kidney 293 cells.''; PubMed Europe PMC Scholia
11. Pandey A, Liu X, Dixon JE, Di Fiore PP, Dixit VM.; ''Direct association between the Ret receptor tyrosine kinase and the Src homology 2-containing adapter protein Grb7.''; PubMed Europe PMC Scholia
12. Cantwell-Dorris ER, O'Leary JJ, Sheils OM.; ''BRAFV600E: implications for carcinogenesis and molecular therapy.''; PubMed Europe PMC Scholia
13. Asai N, Murakami H, Iwashita T, Takahashi M.; ''A mutation at tyrosine 1062 in MEN2A-Ret and MEN2B-Ret impairs their transforming activity and association with shc adaptor proteins.''; PubMed Europe PMC Scholia
14. Plotnikov A, Zehorai E, Procaccia S, Seger R.; ''The MAPK cascades: signaling components, nuclear roles and mechanisms of nuclear translocation.''; PubMed Europe PMC Scholia
15. Brown MD, Sacks DB.; ''Protein scaffolds in MAP kinase signalling.''; PubMed Europe PMC Scholia
16. Pelicci G, Troglio F, Bodini A, Melillo RM, Pettirossi V, Coda L, De Giuseppe A, Santoro M, Pelicci PG.; ''The neuron-specific Rai (ShcC) adaptor protein inhibits apoptosis by coupling Ret to the phosphatidylinositol 3-kinase/Akt signaling pathway.''; PubMed Europe PMC Scholia
17. Jing S, Yu Y, Fang M, Hu Z, Holst PL, Boone T, Delaney J, Schultz H, Zhou R, Fox GM.; ''GFRalpha-2 and GFRalpha-3 are two new receptors for ligands of the GDNF family.''; PubMed Europe PMC Scholia
18. Besset V, Scott RP, Ibáñez CF.; ''Signaling complexes and protein-protein interactions involved in the activation of the Ras and phosphatidylinositol 3-kinase pathways by the c-Ret receptor tyrosine kinase.''; PubMed Europe PMC Scholia
19. Grimm J, Sachs M, Britsch S, Di Cesare S, Schwarz-Romond T, Alitalo K, Birchmeier W.; ''Novel p62dok family members, dok-4 and dok-5, are substrates of the c-Ret receptor tyrosine kinase and mediate neuronal differentiation.''; PubMed Europe PMC Scholia
20. 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
21. Murakami H, Iwashita T, Asai N, Shimono Y, Iwata Y, Kawai K, Takahashi M.; ''Enhanced phosphatidylinositol 3-kinase activity and high phosphorylation state of its downstream signalling molecules mediated by ret with the MEN 2B mutation.''; PubMed Europe PMC Scholia
22. Hayashi H, Ichihara M, Iwashita T, Murakami H, Shimono Y, Kawai K, Kurokawa K, Murakumo Y, Imai T, Funahashi H, Nakao A, Takahashi M.; ''Characterization of intracellular signals via tyrosine 1062 in RET activated by glial cell line-derived neurotrophic factor.''; PubMed Europe PMC Scholia
23. 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
24. 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
25. Melillo RM, Santoro M, Ong SH, Billaud M, Fusco A, Hadari YR, Schlessinger J, Lax I.; ''Docking protein FRS2 links the protein tyrosine kinase RET and its oncogenic forms with the mitogen-activated protein kinase signaling cascade.''; PubMed Europe PMC Scholia
26. Milbrandt J, de Sauvage FJ, Fahrner TJ, Baloh RH, Leitner ML, Tansey MG, Lampe PA, Heuckeroth RO, Kotzbauer PT, Simburger KS, Golden JP, Davies JA, Vejsada R, Kato AC, Hynes M, Sherman D, Nishimura M, Wang LC, Vandlen R, Moffat B, Klein RD, Poulsen K, Gray C, Garces A, Johnson EM.; ''Persephin, a novel neurotrophic factor related to GDNF and neurturin.''; PubMed Europe PMC Scholia
27. Kim B, Cheng HL, Margolis B, Feldman EL.; ''Insulin receptor substrate 2 and Shc play different roles in insulin-like growth factor I signaling.''; PubMed Europe PMC Scholia
28. Ohiwa M, Murakami H, Iwashita T, Asai N, Iwata Y, Imai T, Funahashi H, Takagi H, Takahashi M.; ''Characterization of Ret-Shc-Grb2 complex induced by GDNF, MEN 2A, and MEN 2B mutations.''; PubMed Europe PMC Scholia
29. Alberti L, Borrello MG, Ghizzoni S, Torriti F, Rizzetti MG, Pierotti MA.; ''Grb2 binding to the different isoforms of Ret tyrosine kinase.''; PubMed Europe PMC Scholia
30. Pandey A, Duan H, Di Fiore PP, Dixit VM.; ''The Ret receptor protein tyrosine kinase associates with the SH2-containing adapter protein Grb10.''; PubMed Europe PMC Scholia
31. Leppänen VM, Bespalov MM, Runeberg-Roos P, Puurand U, Merits A, Saarma M, Goldman A.; ''The structure of GFRalpha1 domain 3 reveals new insights into GDNF binding and RET activation.''; PubMed Europe PMC Scholia
32. Roskoski R.; ''MEK1/2 dual-specificity protein kinases: structure and regulation.''; PubMed Europe PMC Scholia
33. Durick K, Wu RY, Gill GN, Taylor SS.; ''Mitogenic signaling by Ret/ptc2 requires association with enigma via a LIM domain.''; PubMed Europe PMC Scholia
34. Jing S, Wen D, Yu Y, Holst PL, Luo Y, Fang M, Tamir R, Antonio L, Hu Z, Cupples R, Louis JC, Hu S, Altrock BW, Fox GM.; ''GDNF-induced activation of the ret protein tyrosine kinase is mediated by GDNFR-alpha, a novel receptor for GDNF.''; PubMed Europe PMC Scholia
35. Baloh RH, Tansey MG, Lampe PA, Fahrner TJ, Enomoto H, Simburger KS, Leitner ML, Araki T, Johnson EM, Milbrandt J.; ''Artemin, a novel member of the GDNF ligand family, supports peripheral and central neurons and signals through the GFRalpha3-RET receptor complex.''; PubMed Europe PMC Scholia
36. Hayashi Y, Iwashita T, Murakamai H, Kato Y, Kawai K, Kurokawa K, Tohnai I, Ueda M, Takahashi M.; ''Activation of BMK1 via tyrosine 1062 in RET by GDNF and MEN2A mutation.''; PubMed Europe PMC Scholia
37. Iwashita T, Asai N, Murakami H, Matsuyama M, Takahashi M.; ''Identification of tyrosine residues that are essential for transforming activity of the ret proto-oncogene with MEN2A or MEN2B mutation.''; PubMed Europe PMC Scholia
38. Roskoski R.; ''RAF protein-serine/threonine kinases: structure and regulation.''; PubMed Europe PMC Scholia
39. Takeda K, Kato M, Wu J, Iwashita T, Suzuki H, Takahashi M, Nakashima I.; ''Osmotic stress-mediated activation of RET kinases involves intracellular disulfide-bonded dimer formation.''; PubMed Europe PMC Scholia
40. Creedon DJ, Tansey MG, Baloh RH, Osborne PA, Lampe PA, Fahrner TJ, Heuckeroth RO, Milbrandt J, Johnson EM.; ''Neurturin shares receptors and signal transduction pathways with glial cell line-derived neurotrophic factor in sympathetic neurons.''; PubMed Europe PMC Scholia
41. Ross D, Joyner WL.; ''Resting distribution and stimulated translocation of protein kinase C isoforms alpha, epsilon and zeta in response to bradykinin and TNF in human endothelial cells.''; PubMed Europe PMC Scholia
42. Kyriakis JM, Avruch J.; ''Mammalian MAPK signal transduction pathways activated by stress and inflammation: a 10-year update.''; PubMed Europe PMC Scholia
43. Roskoski R.; ''ERK1/2 MAP kinases: structure, function, and regulation.''; PubMed Europe PMC Scholia
44. Crowder RJ, Enomoto H, Yang M, Johnson EM, Milbrandt J.; ''Dok-6, a Novel p62 Dok family member, promotes Ret-mediated neurite outgrowth.''; PubMed Europe PMC Scholia
45. Andreozzi F, Melillo RM, Carlomagno F, Oriente F, Miele C, Fiory F, Santopietro S, Castellone MD, Beguinot F, Santoro M, Formisano P.; ''Protein kinase Calpha activation by RET: evidence for a negative feedback mechanism controlling RET tyrosine kinase.''; PubMed Europe PMC Scholia
46. Ichihara M, Murakumo Y, Takahashi M.; ''RET and neuroendocrine tumors.''; PubMed Europe PMC Scholia
47. Cseh B, Doma E, Baccarini M.; ''"RAF" neighborhood: protein-protein interaction in the Raf/Mek/Erk pathway.''; PubMed Europe PMC Scholia
48. Encinas M, Crowder RJ, Milbrandt J, Johnson EM.; ''Tyrosine 981, a novel ret autophosphorylation site, binds c-Src to mediate neuronal survival.''; PubMed Europe PMC Scholia
49. Turjanski AG, Vaqué JP, Gutkind JS.; ''MAP kinases and the control of nuclear events.''; PubMed Europe PMC Scholia
50. Roberts PJ, Der CJ.; ''Targeting the Raf-MEK-ERK mitogen-activated protein kinase cascade for the treatment of cancer.''; PubMed Europe PMC Scholia
51. Fukuda T, Kiuchi K, Takahashi M.; ''Novel mechanism of regulation of Rac activity and lamellipodia formation by RET tyrosine kinase.''; PubMed Europe PMC Scholia

History

External references

DataNodes

Name	Type	Database reference	Comment
2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:GAB1,GAB2	Complex	R-HSA-8855090 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:p-5Y-GAB1,p-5Y-GAB2:PTPN11	Complex	R-HSA-8855762 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:p-5Y-GAB1,p-5Y-GAB2:p85-containing Class 1A PI3Ks	Complex	R-HSA-8855523 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:p-5Y-GAB1,p-5Y-GAB2	Complex	R-HSA-8855302 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1	Complex	R-HSA-8854907 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:DOK1,DOK2,DOK4,DOK5,DOK6	Complex	R-HSA-8855573 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:FRS2	Complex	R-HSA-8855579 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:GRB2-1:SOS1	Complex	R-HSA-8854903 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:GRB7,GRB10	Complex	R-HSA-8854768 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:PLCG1	Complex	R-HSA-8854776 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:RET interactors	Complex	R-HSA-8855914 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:SHC1	Complex	R-HSA-8854400 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:SRC-1,RAP1GAP	Complex	R-HSA-8855748 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:p-Y349,Y350,Y427-SHC1:GRB2-1:SOS1	Complex	R-HSA-8854399 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:p-Y349,Y350,Y427-SHC1	Complex	R-HSA-8854980 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes	Complex	R-HSA-8854160 (Reactome)
2x p-S696-RET:GFRA:GDNF complexes	Complex	R-HSA-8855760 (Reactome)
2x RET:GFRA:GDNF complexes	Complex	R-HSA-8853818 (Reactome)
ADP	Metabolite	CHEBI:456216 (ChEBI)
ARTN	Protein	Q5T4W7 (Uniprot-TrEMBL)
ARTN	Protein	Q5T4W7 (Uniprot-TrEMBL)
ATP	Metabolite	CHEBI:30616 (ChEBI)
DOK1	Protein	Q99704 (Uniprot-TrEMBL)
DOK1,DOK2,DOK4,DOK5,DOK6	Complex	R-HSA-8855619 (Reactome)
DOK2	Protein	O60496 (Uniprot-TrEMBL)
DOK4	Protein	Q8TEW6 (Uniprot-TrEMBL)
DOK5	Protein	Q9P104 (Uniprot-TrEMBL)
DOK6	Protein	Q6PKX4 (Uniprot-TrEMBL)
FRS2	Protein	Q8WU20 (Uniprot-TrEMBL)
FRS2	Protein	Q8WU20 (Uniprot-TrEMBL)
GAB1	Protein	Q13480 (Uniprot-TrEMBL)
GAB1,GAB2	Complex	R-HSA-8855092 (Reactome)
GAB2	Protein	Q9UQC2 (Uniprot-TrEMBL)
GDNF	Protein	P39905 (Uniprot-TrEMBL)
GDNF,NRTN	Complex	R-HSA-8853802 (Reactome)
GFRA1	Protein	P56159 (Uniprot-TrEMBL)
GFRA1, GFRA2	Complex	R-HSA-8853803 (Reactome)
GFRA1,GFRA3	Complex	R-HSA-8853799 (Reactome)
GFRA2	Protein	O00451 (Uniprot-TrEMBL)
GFRA3	Protein	O60609 (Uniprot-TrEMBL)
GFRA4	Protein	Q9GZZ7 (Uniprot-TrEMBL)
GFRA4	Protein	Q9GZZ7 (Uniprot-TrEMBL)
GRB10	Protein	Q13322 (Uniprot-TrEMBL)
GRB2-1	Protein	P62993-1 (Uniprot-TrEMBL)
GRB2-1:SOS1	Complex	R-HSA-109797 (Reactome)
GRB2-1	Protein	P62993-1 (Uniprot-TrEMBL)
GRB7	Protein	Q14451 (Uniprot-TrEMBL)
GRB7,GRB10	Complex	R-HSA-8854773 (Reactome)
IRS2	Protein	Q9Y4H2 (Uniprot-TrEMBL)
MAPK7	Protein	Q13164 (Uniprot-TrEMBL)
NRTN	Protein	Q99748 (Uniprot-TrEMBL)
PDLIM7	Protein	Q9NR12 (Uniprot-TrEMBL)
PIK3CA	Protein	P42336 (Uniprot-TrEMBL)
PIK3CB	Protein	P42338 (Uniprot-TrEMBL)
PIK3CD	Protein	O00329 (Uniprot-TrEMBL)
PIK3R1	Protein	P27986 (Uniprot-TrEMBL)
PIK3R2	Protein	O00459 (Uniprot-TrEMBL)
PIK3R3	Protein	Q92569 (Uniprot-TrEMBL)
PLCG1	Protein	P19174 (Uniprot-TrEMBL)
PLCG1	Protein	P19174 (Uniprot-TrEMBL)
PRKACA	Protein	P17612 (Uniprot-TrEMBL)
PRKACB	Protein	P22694 (Uniprot-TrEMBL)
PRKACG	Protein	P22612 (Uniprot-TrEMBL)
PRKCA	Protein	P17252 (Uniprot-TrEMBL)
PSPN	Protein	O60542 (Uniprot-TrEMBL)
PSPN	Protein	O60542 (Uniprot-TrEMBL)
PTPN11	Protein	Q06124 (Uniprot-TrEMBL)
PTPN11	Protein	Q06124 (Uniprot-TrEMBL)
Protein kinase A catalytic subunit	Complex	R-HSA-425833 (Reactome)
RAF/MAP kinase cascade	Pathway	R-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).
RAP1GAP	Protein	P47736 (Uniprot-TrEMBL)
RET	Protein	P07949 (Uniprot-TrEMBL)
RET interactors	Complex	R-HSA-8855913 (Reactome)
RET:GFRA1,GFRA2:GDNF,NRTN	Complex	R-HSA-8853805 (Reactome)
RET:GFRA1,GFRA2	Complex	R-HSA-8855759 (Reactome)
RET:GFRA1,GFRA3:ARTN	Complex	R-HSA-8853795 (Reactome)
RET:GFRA1,GFRA3	Complex	R-HSA-8855745 (Reactome)
RET:GFRA4:PSPN	Complex	R-HSA-8853798 (Reactome)
RET:GFRA4	Complex	R-HSA-8855751 (Reactome)
RET:GFRA:GDNF complexes	Complex	R-HSA-8853817 (Reactome)
RET	Protein	P07949 (Uniprot-TrEMBL)
SHANK3	Protein	Q9BYB0 (Uniprot-TrEMBL)
SHC1	Protein	P29353 (Uniprot-TrEMBL)
SHC1	Protein	P29353 (Uniprot-TrEMBL)
SHC3	Protein	Q92529 (Uniprot-TrEMBL)
SOS1	Protein	Q07889 (Uniprot-TrEMBL)
SRC-1	Protein	P12931-1 (Uniprot-TrEMBL)
SRC-1, RAP1GAP	Complex	R-HSA-8855753 (Reactome)
p-5Y-GAB1	Protein	Q13480 (Uniprot-TrEMBL)
p-5Y-GAB2	Protein	Q9UQC2 (Uniprot-TrEMBL)
p-5Y-RET	Protein	P07949 (Uniprot-TrEMBL)
p-5Y-RET:GDNF:GFRA complexes with and without p-SHC1	Complex	R-HSA-8854900 (Reactome)
p-Y349,Y350,Y427-SHC1	Protein	P29353 (Uniprot-TrEMBL)
p85-containing Class 1A PI3Ks	Complex	R-HSA-508248 (Reactome)	This set represents Class 1A PI3Ks including all three genes that can give rise to the five isoforms of the regulatory subunit. Note that the p85 alpha form is almost always the form used as a reagent experimentally and measured by p85-Abs.The other forms are rarely used or determined experimentally. Also note that Class 1A PI3Ks may not be the most relevant physiologically in some cell types (e.g. T cells). There are five variants of the p85 regulatory subunit, designated p85alpha, p55alpha, p50alpha, p85beta, and p55gamma. There are also three variants of the p110 catalytic subunit designated p110alpha, beta, or gamma catalytic subunit. The first three regulatory subunits are all splice variants of the same gene (Pik3r1), the other two are expressed by Pik3r2 and Pik3r3, respectively). The most highly expressed regulatory subunit is p85alpha. All three catalytic subunits are expressed by separate genes (Pik3ca, Pik3cb, and Pik3cd for p110alpha, p110beta and p110gamma, respectively). The alpha and beta p110s are expressed in all cells, while p110gamma is expressed primarily in leukocytes. It has been suggested that it evolved in parallel with the adaptive immune system. The regulatory p101 and catalytic p110gamma subunits comprise the class IB PI3Ks, each is encoded by a single gene.

Annotated Interactions

Source	Target	Type	Database reference	Comment
	2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:GAB1,GAB2	Arrow	R-HSA-8854897 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:GAB1,GAB2			R-HSA-8853774 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:p-5Y-GAB1,p-5Y-GAB2:PTPN11	Arrow	R-HSA-8855508 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:p-5Y-GAB1,p-5Y-GAB2:p85-containing Class 1A PI3Ks	Arrow	R-HSA-8854905 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:p-5Y-GAB1,p-5Y-GAB2	Arrow	R-HSA-8853774 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:p-5Y-GAB1,p-5Y-GAB2			R-HSA-8854905 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1:p-5Y-GAB1,p-5Y-GAB2			R-HSA-8855508 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1	Arrow	R-HSA-8853793 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes with, without p-SHC1:GRB2-1			R-HSA-8854897 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes:DOK1,DOK2,DOK4,DOK5,DOK6	Arrow	R-HSA-8855617 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes:FRS2	Arrow	R-HSA-8855564 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes:GRB2-1:SOS1	Arrow	R-HSA-8854899 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes:GRB7,GRB10	Arrow	R-HSA-8853753 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes:PLCG1	Arrow	R-HSA-8853755 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes:RET interactors	Arrow	R-HSA-8855915 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes:SHC1	Arrow	R-HSA-8853737 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:SHC1			R-HSA-8854981 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes:SRC-1,RAP1GAP	Arrow	R-HSA-8855747 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes:p-Y349,Y350,Y427-SHC1:GRB2-1:SOS1	Arrow	R-HSA-8853734 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes:p-Y349,Y350,Y427-SHC1	Arrow	R-HSA-8854981 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes:p-Y349,Y350,Y427-SHC1			R-HSA-8853734 (Reactome)
	2x p-5Y-RET:GDNF:GFRA complexes	Arrow	R-HSA-8853792 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes			R-HSA-8853737 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes			R-HSA-8853753 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes			R-HSA-8853755 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes			R-HSA-8854899 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes			R-HSA-8855564 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes			R-HSA-8855617 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes			R-HSA-8855747 (Reactome)
2x p-5Y-RET:GDNF:GFRA complexes			R-HSA-8855915 (Reactome)
	2x p-S696-RET:GFRA:GDNF complexes	Arrow	R-HSA-8854908 (Reactome)
	2x RET:GFRA:GDNF complexes	Arrow	R-HSA-8853762 (Reactome)
2x RET:GFRA:GDNF complexes			R-HSA-8853792 (Reactome)
2x RET:GFRA:GDNF complexes			R-HSA-8854908 (Reactome)
2x RET:GFRA:GDNF complexes		mim-catalysis	R-HSA-8853792 (Reactome)
	ADP	Arrow	R-HSA-8853774 (Reactome)
	ADP	Arrow	R-HSA-8853792 (Reactome)
	ADP	Arrow	R-HSA-8854908 (Reactome)
ARTN			R-HSA-8853800 (Reactome)
ATP			R-HSA-8853774 (Reactome)
ATP			R-HSA-8853792 (Reactome)
ATP			R-HSA-8854908 (Reactome)
DOK1,DOK2,DOK4,DOK5,DOK6			R-HSA-8855617 (Reactome)
FRS2			R-HSA-8855564 (Reactome)
GAB1,GAB2			R-HSA-8854897 (Reactome)
GDNF,NRTN			R-HSA-8853789 (Reactome)
GFRA1, GFRA2			R-HSA-8871226 (Reactome)
GFRA1,GFRA3			R-HSA-8853745 (Reactome)
GFRA4			R-HSA-8871227 (Reactome)
GRB2-1:SOS1			R-HSA-8853734 (Reactome)
GRB2-1:SOS1			R-HSA-8854899 (Reactome)
GRB2-1			R-HSA-8853793 (Reactome)
GRB7,GRB10			R-HSA-8853753 (Reactome)
PLCG1			R-HSA-8853755 (Reactome)
PSPN			R-HSA-8853801 (Reactome)
PTPN11			R-HSA-8855508 (Reactome)
Protein kinase A catalytic subunit		mim-catalysis	R-HSA-8854908 (Reactome)
			R-HSA-8853734 (Reactome)	RET has been shown to bind GRB2 indirectly via SHC (Ohiwa et al. 1997). GRB2 is found in a complex with SOS1 in unstimulated cells (Hayashi et al. 2000). GDNF stimulation of neuronal cells induces the assembly of a large protein complex containing RET, GRB2 and tyrosine-phosphorylated SHC, p85 subunit of (PI3K), GAB2 (GAB1 in Hayashi et al. 2000) and Tyrosine-protein phosphatase non-receptor type 11 (PTPN11, SHP-2) (Besset et al. 2000). This suggests that at least two distinct RET-SHC protein complexes can assemble via phosphorylated Tyrosine (Y) 1062, one involving GRB2:SOS1 leads to activation of the Ras/Erk pathway, another involving GRB1/2, GAB2 and PI3K leads to the PI3K/Akt pathway. This latter complex can also assemble directly onto phosphorylated Y1096 (Besset et al. 2000). RET can activate the RAS-RAF-ERK signaling pathway (van Weering et al. 1995, Ohiwa et al. 1997, van Weering & Bos 1997, Trupp et al. 1999, Hayashi et al. 2000). RAS signaling is markedly impaired by mutations of RET Y1062 (Hayashi et al. 2000). RET RAS signaling and the effect of the Y1062 mutation are believed to be mediated by RET complexes involving GRB2:SOS, well known as mediators of signaling to RAS in other receptor systems (Ravichandran 2001).
			R-HSA-8853737 (Reactome)	GDNF stimulation of neuronal cells induces the assembly of a large protein complex containing RET, GRB2 and tyrosine-phosphorylated SHC1, p85 subunit of (PI3K), GAB2 (GAB1 in Hayashi et al. 2000) and Tyrosine-protein phosphatase non-receptor type 11 (PTPN11, SHP-2) (Besset et al. 2000). RET binds SHC1 via phosphorylated tyrosine-1062 (Asai et al. 1996, Arighi et al. 1997).
			R-HSA-8853745 (Reactome)	RET is a receptor tyrosine kinase with a cadherin-related motif and a cysteine-rich domain in the extracellular domain (Takahashi et al. 1988). It is the receptor for members of the glial cell-derived neurotrophic factor (GDNF) family of ligands (Lin et al. 1993, Kotzbauer et al. 1996, Baloh et al. 1998, Milbrandt et al. 1998). RET can only bind these ligands in the presence of a co-receptor from the family of glycosylphosphatidylinositol (GPI)-anchored co-receptors collectively termed GDNF family receptor-alpha (GFRA) (Treanor et al. 1996, Jing et al. 1996, Plaza-Menacho et al. 2006). Early models proposed that GDNF formed a complex with GFRA1 and subsequently recruited RET (Massagué et al. 1996). Current models suggest that GFRA and RET pre-associate before ligand binding, based on binding and site-directed mutagenesis studies (Eketjäll et al. 1999, Cik et al. 2000). An alternative model suggests that GPI-anchored GFRA recruits RET to lipid rafts after GDNF stimulation (Tansey et al. 2000). The stoichiometry as well as the kinetics of ligand-receptor complex formation are not well understood. It is believed that all GDNF family members interact with their cognate co-receptor and activate RET in a similar manner to GDNF (Airaksinen & Saarma 2002).
			R-HSA-8853753 (Reactome)	Tyrosine-phosphorylated RET can bind GRB7 or GRB10 via tyrosine-905 (Pandey et al. 1995, 1996).
			R-HSA-8853755 (Reactome)	Phosphorylated RET binds Phospholipase C gamma 1 (PLCG1) via tyrosine 905 (Borello et al. 1996) and/or tyrosine-1015 (Lundgren et al. 2012).
			R-HSA-8853762 (Reactome)	It is widely accepted that RET undergoes dimerization and transphosphorylation following Glial cell line-derived neurotrophic factor (GDNF) binding to the GDNF-family receptor:RET complex. Transphosphorylation of specific tyrosine residues is a prerequisite for activation of RET tyrosine kinase activity and downstream signaling (Santoro et al. 1995, Airaksinen et al. 1999, Takeda et al. 2001, Leppänen et al. 2004). However, self-association of RET in the absence of GDNF has been reported and may contribute to the mechanism of RET activation (Kjaer et al. 2006). The stoichiometry and kinetics of ligand-receptor complex formation are not well understood. It is assumed that all GDNF family of ligands (GFL) members interact with their cognate co-receptor and activate RET in a similar manner to GDNF (Airaksinen & Saarma 2002).
			R-HSA-8853774 (Reactome)	Grb2-associated-binder (GAB) family signaling is mediated by tyrosine phosphorylation. GAB1-3 all have an N-terminal pleckstrin homology (PH) domain, proline-rich motifs, and multiple potential tyrosyl and seryl/threonyl phosphorylation sites (Gu & Neel 2003, Liu & Rohrschneider 2002). GAB2 has several docking sites for SH2 domain-containing molecules, including tyrosine-protein phosphatase non-receptor type 11 (PTPN11, SHP-2) and the p85 subunit of phosphatidylinositol 3-kinase (p85-PI3K) (Ding et al. 2015). Similarly, GAB1 associates with PTPN11 and p85-PI3K; these interactions are considered essential for GAB1 activation of extracellular signal-regulated kinase (ERK)1/2 and PI3K-AKT, respectively (Wang et al. 2015). GAB2 has three tyrosine (Y) residues, Y452, Y476 and Y584, that are binding sites for p85-PI3K (Crouin et al. 2001, Maus et al. 2009) and two more (Y614 and Y643) that interact with the SH2 domains of PTPN11 (Gu et al. 1998, Crouin et al. 2001, Arnaud et al. 2004). GAB1 also becomes tyrosine phosphorylated when transducing signals from receptor tyrosine kinases to p85 (Holgado-Madruga et al. 1997, Mattoon et al. 2004). There are three potential binding sites for p85 on GAB1 (Y447, Y472, and Y589) (Holgado-Madruga et al. 1997). GAB1 Y627 and Y659 appear to link it to PTPN11; GAB1 mutants that are unable to bind PTPN11 do not activate ERK (Schaeper et al. 2000, Cunnick et al. 2000, Sármay et al. 2006). PI3K activation produces membrane-associated PI(3,4,5)P3, which facilitates membrane association of the PH domain of GAB, enhancing its recruitment (Zhang et al. 2009) in a positive feed-back loop. The kinases responsible for GAB phosphorylation are cell-type and receptor specific (Maus et al. 2009). GDNF stimulation of neuronal cells induces the assembly of a complex containing RET, GRB2 and tyrosine-phosphorylated SHC, p85 subunit of (PI3K), GAB2 (GAB1 in Hayashi et al. 2000) and PTPN11 (SHP2) (Besset et al. 2000). GAB1 was found in complexes with GRB2 only after GDNF treatment (Hayashi et al. 2000). The likely order of recruitment to RET is SHC, GRB2, GAB1/2, p85 and/or PTPN11, similar to the signaling mechanism of the Interleukin-3 receptor (Gu et al. 2000) and others (Adams et al. 2012, Ding et al. 2015). It is likely, though not demonstrated, that GAB1/2 become tyrosine phosphorylated after binding GRB2 in the RET receptor complex. The kinase responsible is unclear. As the order of GAB binding and phosphorylation, and the identity of the kinase responsible for GAB phosphorylation have not been demonstrated, GAB phosphorylation in the RET complex is shown as an uncertain event.
			R-HSA-8853789 (Reactome)	Glial cell-derived neurotrophic factor (GDNF) (Lin et al. 1993) and neurturin (NRTN) (Kotzbauer et al. 1996) are ligands for GDNF family receptor-alpha (GFRA) 1 and 2 (Jing et al. 1996, 1997, Creedon et al. 1997, Baloh et al. 1997). Despite the cross activation in vitro, GDNF preferentially acts through RET:GFRA1 (Schuchardt et al. 1994, Moore et al. 1996, Pichel et al. 1996, Sanchez et al. 1996, Calcano et al. 1998, Endomoto et al. 1998, whereas NRTN preferentially acts through RET: GFRA2 (Heuckeroth et al. 1999, Rossi et al. 1999, Luo et al. 2004, 2009, Lindfors et al. 2006) in vivo.
			R-HSA-8853792 (Reactome)	RET undergoes trans-autophosphorylation on specific tyrosine (Y) residues. The short and medium-length isoforms of RET contain 16 tyrosine residues; 10 in the kinase domain, 2 in the juxtamembrane domain, 1 in the kinase insert and 3 in the carboxy-terminal tail. The long RET isoform has 2 additional tyrosines in the carboxy-terminal tail. Phosphorylation of Y905 stabilizes the active conformation of the kinase and facilitates the autophosphorylation of Y residues mainly located in the C-terminal tail (Iwashita et al. 1996, Kawamoto et 2004). Y905, 1015, 1062 and 1096 are binding sites for GRB7/GRB10, phospholipase Cgamma (PLCG1), SHC1 and GRB2, respectively (Ichihara et al. 2004, Murakumo et al. 2006). Y1096 is present only in the long isoform. Phosphorylated Y981 is reported to bind SRC (Encinas et al. 2004). RET can activate various signaling pathways including RAS-RAF-ERK (van Weering et al. 1995, Ohiwa et al. 1997, van Weering & Bos 1997, Trupp et al. 1999, Hayashi et al. 2000), phosphatidylinositol 3-kinase (PI3K)/AKT (Murakami et al. 1999a, Murakami et al. 1999b, Trupp et al. 1999, Soler et al. 1999, Segouffin-Cariou & Billaud 2000, Hayashi et al. 2000), p38 mitogen-activated protein kinase (MAPK) (Worby et al. 1996, Feng et al. 1999) and c-Jun N-terminal kinase (JNK) pathways (Xing et al. 1998, Chiariello et al. 1998). All these pathways are activated mainly through Y1062 (Hayashi et al. 2000). Point mutations at Y1062 result in a severe loss-of-function phenotype (Ibáñez 2013). SHC1 further associates with GRB2 and GAB1/GAB2, all of which become tyrosine phosphorylated. Tyrosine-phosphorylated GAB1/2 associates with the p85 subunit of PI3K, resulting in PI3K and AKT activation (Murakami et al. 1999b, Hayashi et al. 2000, Besset et al. 2000). GRB2-GAB1/2 can also assemble directly onto phosphorylated Y1096, an alternative route to PI3K activation (Besset et al. 2000). SHC1 can also form a complex with GRB2:SOS leading to activation of the RAS-RAF-ERK pathway (Hayashi et al. 2000). However, mutation of Y1062 did not completely abolish activation of the RAS-RAF-ERK and PI3K-AKT pathways suggesting alternative signaling pathways (Ichihara et al. 2004). The adaptor protein FRS2 can bind phosphorylated Y1062 (Kurokawa et al. 2001, Melillo et al. 2001), competing with SHC1 (Lundgren et al. 2006). Differential signaling may be mediated by different compartments in the plasma membrane, as RET has been shown to interact with FRS2 in lipid rafts, but with SHC1 outside lipid rafts (Paratcha et al. 2001). Many other proteins have been shown to bind and/or become activated via Y1062. Docking protein 1 (DOK1), 2, 4, 5, and 6 adaptor proteins all interact with phosphorylated Y1062 (Grimm et al. 2001; Crowder et al. 2004; Kurotsuchi et al. 2010). Other suggested RET interactors include Mitogen-activated protein kinase 7 (MAPK7, BMK1) (Hayashi et al. 2001), SH3 and multiple ankyrin repeat domains protein 3 (SHANK3) (Schuetz et al. 2004), Insulin receptor substrate-2 (IRS2) (Hennige et al. 2000), SHC-transforming protein 3 (SHC3) (Pelicci et al. 2002), Protein kinase C alpha (PKCA) (Andreozzi et al. 2003) and PDZ and LIM domain protein 7 (Enigma, PDLIM7) (Durick et al. 1996). PDLIM7 and SHANK3 bind Y1062 regardless of its phosphorylation state. Rap1GAP can bind phosphorylated Y981 to suppress GDNF-induced activation of ERK and neurite outgrowth (Jiao et al. 2011). Tyrosine-protein phosphatase non-receptor type 11 (PTPN11, SHP2) binds to phosphorylated Y687 and components of the Y1062 associated signaling complex, contributing to activation of PI3K/AKT and promoting survival and neurite outgrowth in primary neurons (Besset et al. 2000, Perrinjaquet et al. 2010). It is unclear how RET activates the p38MAPK, JNK, and ERK5 signaling pathways (Ichihara et al. 2004). To simplify the representation of RET signaling, all RET tyrosines known to be involved in signalling are phosphorylated in this event.
			R-HSA-8853793 (Reactome)	GDNF stimulation of neuronal cells induces the assembly of a large protein complex containing RET, GRB2 and tyrosine-phosphorylated SHC1, p85 subunit of (PI3K), GAB2 (GAB1 in Hayashi et al. 2000), and Tyrosine-protein phosphatase non-receptor type 11 (PTPN11, SHP-2) (Besset et al. 2000). GAB1 was found in complexes with GRB2 only after GDNF treatment (Hayashi et al. 2000). This contrasts with reports in other systems where GAB2-GRB2 were reported to constitutively associate (Gu et al. 1998). The likely order of recruitment to RET is SHC1, GRB2, GAB1/2, similar to the signaling mechanism of the Interleukin-3 receptor (Gu et al. 2000) and many others (Adams et al. 2012).
			R-HSA-8853800 (Reactome)	Artemin (ARTN) is a ligand for GDNF family receptor-alpha (GFRA) 1 and 3, preferentially binding GFRA3 (Baloh et al. 1998).
			R-HSA-8853801 (Reactome)	Persephin (PSPN) is a ligand for GDNF family receptor-alpha (GFRA) 4 (Milbrandt et al. 1998, Masure et al. 2000).
			R-HSA-8854897 (Reactome)	Grb-associated binder (GAB) proteins are a family of docking proteins that transduce cellular signals between receptors and intracellular downstream effectors (Ding et al. 2015). When phosphorylated by protein-tyrosine kinases, GABs can recruit several Src homology-2 (SH2) domain-containing proteins, including Tyrosine-protein phosphatase non-receptor type 11 (PTPN11, SHP2), the p85 subunit of phosphoinositide-3 kinase (p85-PI3K), phospholipase C-gamma 1 (PLCG1), CRK and GAB-associated Cdc42/Rac GTPase-activating protein (ARHGAP32, GC-GAP). These interactions lead to various downstream signals involved in cell growth, differentiation, migration and apoptosis. GDNF stimulation of neuronal cells induces the assembly of a large protein complex containing RET, GRB2 and tyrosine-phosphorylated SHC1, p85-PI3K, GAB2 (GAB1 in Hayashi et al. 2000) and PTPN11 (Besset et al. 2000). GAB1 was found in complexes with GRB2 only after GDNF treatment (Hayashi et al. 2000). This contrasts with reports that GAB2 constitutively associates with GRB2 (Gu et al. 1998). The likely order of recruitment to RET is SHC1, GRB2, GAB1/2, p85-PI3K, similar to the signaling mechanism of the Interleukin-3 receptor (Gu et al. 2000) and many others (Adams et al. 2012, Ding et al. 2015). As the order of RET complex formation is not firmly established, GAB binding is shown as an uncertain event.
			R-HSA-8854899 (Reactome)	RET has been shown to bind GRB2 directly, via Tyrosine-1096 (Y1096) (Alberti et al. 1998, Besset et al. 2000). GRB2 is found in a complex with SOS1 in unstimulated cells (Hayashi et al. 2000). GDNF stimulation of neuronal cells induces the assembly of a large protein complex containing RET, GRB2 and tyrosine-phosphorylated SHC1, p85 subunit of (PI3K), GAB2 (GAB1 in Hayashi et al. 2000) and Tyrosine-protein phosphatase non-receptor type 11 (PTPN11, SHP-2) (Besset et al. 2000). This suggests that at least two distinct RET-SHC1 protein complexes can assemble via phosphorylated Y1062, one involving GRB2 and SOS1 leads to activation of the RAS-RAF-ERK pathway, another involving GRB2, GAB2 and p85 leads to the PI3K-AKT pathway. This latter complex can also assemble directly onto phosphorylated Y1096 (Besset et al. 2000). RET can activate the RAS-RAF-ERK signaling pathway (van Weering et al. 1995, Ohiwa et al. 1997, van Weering & Bos 1997, Trupp et al. 1999, Hayashi et al. 2000). RAS signaling is markedly impaired by mutations of RET Y1062 (Hayashi et al. 2000). RET RAS signaling and the effect of the Y1062 mutation are believed to be mediated by RET complexes involving GRB2:SOS1, well known as mediators of signaling to RAS in other receptor systems (Ravichandran 2001).
			R-HSA-8854905 (Reactome)	Following recruitment and phosphorylation of GAB1 or GAB2 to the RET complex, it binds the p85 subunit of p85-containing PI3 kinase (p85-PI3K), resulting in its activation (Murakami et al. 1999, Hayashi et al. 2000, Besset et al. 2000). p85-PI3K consists of a p85 adaptor subunit, which contains one Src homology 3 (SH3) and two Src homology 2 (SH2) domains, and a p110 subunit that has catalytic activity (Kapeller & Cantley 1994). These subunits are tightly associated (Carpenter et al. 1990). Though p85-PI3K can be phosphorylated, it is binding of the p85 SH2 domains that activates the enzyme (Rordorf-Nikolic et al. 1995). GAB2 has three tyrosine residues, Y452, Y476 and Y584, which are involved in p85-PI3K binding (Crouin et al. 2001, Maus et al. 2009). GAB1 also becomes tyrosine phosphorylated and directly associates with p85 when transducing signals from receptor tyrosine kinases to p85 (Holgado-Madruga et al. 1997, Mattoon et al. 2004). There are three potential binding sites for p85 on GAB1 (Y447, Y472, and Y589) (Holgado-Madruga et al. 1997). Phosphorylation at these sites in GAB1 is represented in this reaction as a likely prerequisite for p85 binding, but this is not experimentally confirmed, hence this reaction is displayed as an uncertain event.
			R-HSA-8854908 (Reactome)	Serine (S) 696 in RET is phosphorylated by protein kinase A. Mutation of this serine almost completely inhibits the ability of RET to activate the small GTPase Rac1 and stimulate formation of cell lamellipodia (Fukuda et al. 2002). Homozygous knock-in mice carrying this mutation lacked enteric neurons in the distal colon, resulting from a migration defect of enteric neural crest cells (Asai et al. 2006). The effects of the S696 RET mutant could be alleviated by simultaneous mutation of Tyrosine-687 (Fukuda et al. 2002). Activation of PKA by forskolin was found to impair the recruitment of SHP2 to RET and negatively affect ligand-mediated neurite outgrowth (Perrinjaquet et al. 2010). Mutation of S696 enhanced SHP2 binding and eliminated the effect of forskolin on ligand-induced neurite outgrowth.
			R-HSA-8854981 (Reactome)	GDNF stimulation of neuronal cells induces the assembly of a large protein complex containing RET, GRB2 and tyrosine-phosphorylated SHC1, p85 subunit of (PI3K), GAB2 (GAB1 in Hayashi et al. 2000), and Tyrosine-protein phosphatase non-receptor type 11 (PTPN11, SHP-2) (Besset et al. 2000). Based on the mechanism of SHC1 activation in other receptor systems (Gu et al. 2000) it is likely that SHC1 tyrosine (Y) phosphorylation occurs as a consequence of RET binding and is required for subsequent events. GRB2 binding to SHC1 requires phosphorylation of Y349, Y350 and/or Y427 (Gu et al. 2000). Mutation of RET Y1062, which binds SHC1 to initiate recruitment of GRB2-GAB-p85, did not completely abolish the activation of RAS-RAF-ERK and PI3K-AKT (Besset et al. 2000), suggesting there are alternative pathways that do not utilize SHC1. RET has been shown to bind GRB2 directly, via Y1096 (Alberti et al. 1998, Besset et al. 2000). It has not been established whether SHC1 associates with RET in phosphorylated form or is phosphorylated after binding, and the identity of the kinase is unknown, hence this is represented as an uncertain event.
			R-HSA-8855508 (Reactome)	GDNF stimulation of neuronal cells induces the assembly of a large protein complex containing RET, GRB2 and tyrosine-phosphorylated SHC1, p85 subunit of PI3K, GAB2 (GAB1 in Hayashi et al. 2000), and Tyrosine-protein phosphatase non-receptor type 11 (PTPN11, SHP-2) (Besset et al. 2000). PTPN11 is recruited to RET via a combination of direct interactions and indirect interactions with other components of the receptor complex such as FRS2A and GAB1/2 (Perrinjaquet et al. 2010, Willecke et al. 2011). Binding of PTPN11 SH2-domains induces a conversion of the closed inactive into an open active structure (Willecke et al. 2011). GAB2 interacts with the SH2 domains of PTPN11 (Gu et al. 1998, Crouin et al. 2001, Arnaud et al. 2004), which binds GAB2 Tyrosine (Y) 614 and Y643 through its N- and C-terminal SH2 domains respectively. Mutation of Y614 is sufficient to prevent GAB2 from recruiting PTPN11. In the Interleukin-2 receptor system, this prevents ERK (extracellular-signal-regulated kinase) activation (Arnaud et al. 2004). Similarly, phosphorylated GAB1 binds PTPN11, PI3K, PLCgamma1 and SHC1 in activated B cells (Ingham et al. 1998). GAB1 Y627 and Y659 appear to link it to PTPN11; GAB1 mutants that are unable to bind PTPN11 do not activate ERK (Schaeper et al. 2000, Cunnick et al. 2000, Sármay et al. 2006).
			R-HSA-8855564 (Reactome)	RET can bind FRS2, via phosphotyrosine-1062 (p-Y1062) (Kurokawa et al. 2001, Meillo et al. 2001). FRS2 competes with SHC1 for p-Y1062 binding (Lundgren et al. 2006). RET has been reported to associate with FRS2, instead of SHC1, when associated with lipid rafts (Paratcha et al. 2001).
			R-HSA-8855617 (Reactome)	Docking protein 1 (DOK 1), 2, 4, 5, and 6 adaptor proteins all interact with RET at phosphorylated tyrosine-1062 (Y1062) (Grimm et al. 2001, Crowder et al. 2004, Kurotsuchi et al. 2010). DOKs are adaptor proteins that can inhibit mitogen-activated protein kinase (MAPK) signaling, cell proliferation, and cellular transformation. DOK1 and 2 may exert their inhibitory effects by recruiting Ras GTPase-activating protein 1 (RASA1, RasGAP), which is a negative regulator of Ras signaling, but DOK2 can attenuate EGF receptor-induced MAP kinase activation without RASA1. DOK3 negatively regulates signaling by recruiting INPP5D and CSK (Grimm et al. 2001). RET promotes neurite outgrowth of the rat pheochromocytoma cell line PC12 via Y1062. RET-DOK4/5 fusion proteins induced ligand-dependent axonal outgrowth of PC12 cells, while RET-DOK2 fusions did not. DOK4/5 do not associate with RASA1 or NCK, and enhance RET-dependent activation of MAPK (Grimm et al. 2001).
			R-HSA-8855747 (Reactome)	RET phospho-Tyr981 binds the cytoplasmic tyrosine kinase SRC (Encinas et al. 2004). Recently, a yeast-two-hybrid screen led to the identification of the GTPase-activating protein (GAP) for Rap1, RAP1GAP, as a novel RET-binding protein (Jiao et al. 2011). Like SRC, Rap1GAP was also found to require phosphorylation of Tyrosine-981 for RET binding and suppressed GDNF-induced activation of ERK and neurite outgrowth.
			R-HSA-8855915 (Reactome)	Other RET interactors that may have a role in RET signaling include Mitogen-activated protein kinase 7 (MAPK7, BMK1) (Hayashi et al. 2001), SH3 and multiple ankyrin repeat domains protein 3 (SHANK3) (Schuetz et al. 2004), Insulin receptor substrate-2 (IRS2) (Hennige et al. 2000), SHC-transforming protein 3 (SHC3) (Pelicci et al. 2002), Protein kinase C alpha (PKCA) (Andreozzi et al. 2003) and PDZ and LIM domain protein 7 (Enigma, PDLIM7) (Durick et al. 1996). PDLIM7 and SHANK3 bind Tyrosine-1062 regardless of its phosphorylation state.
			R-HSA-8871226 (Reactome)	RET is a receptor tyrosine kinase with a cadherin-related motif and a cysteine-rich domain in the extracellular domain (Takahashi et al. 1988). It is the receptor for members of the glial cell-derived neurotrophic factor (GDNF) family of ligands (Lin et al. 1993, Kotzbauer et al. 1996, Baloh et al. 1998, Milbrandt et al. 1998). RET can only bind these ligands in the presence of a co-receptor from the family of glycosylphosphatidylinositol (GPI)-anchored co-receptors collectively termed GDNF family receptor-alpha (GFRA) (Treanor et al. 1996, Jing et al. 1996, Plaza-Menacho et al. 2006). Earlier models proposed that GDNF formed a complex with GFRA1 and subsequently recruited RET (Massagué et al. 1996). Current models suggest that GFRA and RET preassociate before ligand binding, based on binding and site-directed mutagenesis studies (Eketjäll et al. 1999, Cik et al. 2000). An alternative model suggests that GPI-anchored GFRA recruits RET to lipid rafts after GDNF stimulation (Tansey et al. 2000). The stoichiometry as well as the kinetics of ligand-receptor complex formation are not well understood. It is believed that all GDNF family members interact with their cognate co-receptor and activate RET in a similar manner to GDNF (Airaksinen & Saarma 2002).
			R-HSA-8871227 (Reactome)	RET is a receptor tyrosine kinase with a cadherin-related motif and a cysteine-rich domain in the extracellular domain (Takahashi et al. 1988). It is the receptor for members of the glial cell-derived neurotrophic factor (GDNF) family of ligands (Lin et al. 1993, Kotzbauer et al. 1996, Baloh et al. 1998, Milbrandt et al. 1998). RET can only bind these ligands in the presence of a co-receptor from the family of glycosylphosphatidylinositol (GPI)-anchored co-receptors collectively termed GDNF family receptor-alpha (GFRA) (Treanor et al. 1996, Jing et al. 1996, Plaza-Menacho et al. 2006). Early models proposed that GDNF formed a complex with GFRA1 and subsequently recruited RET (Massagué et al. 1996). Current models suggest that GFRA and RET preassociate before ligand binding, based on binding and site-directed mutagenesis studies (Eketjäll et al. 1999, Cik et al. 2000). An alternative model suggests that GPI-anchored GFRA recruits RET to lipid rafts after GDNF stimulation (Tansey et al. 2000). The stoichiometry as well as the kinetics of ligand-receptor complex formation are not well understood. It is believed that all GDNF family members interact with their cognate co-receptor and activate RET in a similar manner to GDNF (Airaksinen & Saarma 2002).
RET interactors			R-HSA-8855915 (Reactome)
	RET:GFRA1,GFRA2:GDNF,NRTN	Arrow	R-HSA-8853789 (Reactome)
	RET:GFRA1,GFRA2	Arrow	R-HSA-8871226 (Reactome)
RET:GFRA1,GFRA2			R-HSA-8853789 (Reactome)
	RET:GFRA1,GFRA3:ARTN	Arrow	R-HSA-8853800 (Reactome)
	RET:GFRA1,GFRA3	Arrow	R-HSA-8853745 (Reactome)
RET:GFRA1,GFRA3			R-HSA-8853800 (Reactome)
	RET:GFRA4:PSPN	Arrow	R-HSA-8853801 (Reactome)
	RET:GFRA4	Arrow	R-HSA-8871227 (Reactome)
RET:GFRA4			R-HSA-8853801 (Reactome)
RET:GFRA:GDNF complexes			R-HSA-8853762 (Reactome)
RET			R-HSA-8853745 (Reactome)
RET			R-HSA-8871226 (Reactome)
RET			R-HSA-8871227 (Reactome)
SHC1			R-HSA-8853737 (Reactome)
SRC-1, RAP1GAP			R-HSA-8855747 (Reactome)
p-5Y-RET:GDNF:GFRA complexes with and without p-SHC1			R-HSA-8853793 (Reactome)
p85-containing Class 1A PI3Ks			R-HSA-8854905 (Reactome)