TP53 Regulates Transcription of Cell Death Genes (Homo sapiens)

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1. Wang L, Xing H, Tian Z, Peng L, Li Y, Tang K, Rao Q, Wang M, Wang J.; ''iASPPsv antagonizes apoptosis induced by chemotherapeutic agents in MCF-7 cells and mouse thymocytes.''; PubMed Europe PMC Scholia
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20. Takimoto R, El-Deiry WS.; ''Wild-type p53 transactivates the KILLER/DR5 gene through an intronic sequence-specific DNA-binding site.''; PubMed Europe PMC Scholia
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22. Robles AI, Bemmels NA, Foraker AB, Harris CC.; ''APAF-1 is a transcriptional target of p53 in DNA damage-induced apoptosis.''; PubMed Europe PMC Scholia
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26. Miura M, Zhu H, Rotello R, Hartwieg EA, Yuan J.; ''Induction of apoptosis in fibroblasts by IL-1 beta-converting enzyme, a mammalian homolog of the C. elegans cell death gene ced-3.''; PubMed Europe PMC Scholia
27. Hu Y, Benedict MA, Ding L, Núñez G.; ''Role of cytochrome c and dATP/ATP hydrolysis in Apaf-1-mediated caspase-9 activation and apoptosis.''; PubMed Europe PMC Scholia
28. Andrysik Z, Kim J, Tan AC, Espinosa JM.; ''A genetic screen identifies TCF3/E2A and TRIAP1 as pathway-specific regulators of the cellular response to p53 activation.''; PubMed Europe PMC Scholia
29. Santiago A, Li D, Zhao LY, Godsey A, Liao D.; ''p53 SUMOylation promotes its nuclear export by facilitating its release from the nuclear export receptor CRM1.''; PubMed Europe PMC Scholia
30. Ando K, Kernan JL, Liu PH, Sanda T, Logette E, Tschopp J, Look AT, Wang J, Bouchier-Hayes L, Sidi S.; ''PIDD death-domain phosphorylation by ATM controls prodeath versus prosurvival PIDDosome signaling.''; PubMed Europe PMC Scholia
31. Brough D, Rothwell NJ.; ''Caspase-1-dependent processing of pro-interleukin-1beta is cytosolic and precedes cell death.''; PubMed Europe PMC Scholia
32. Mantovani F, Zannini A, Rustighi A, Del Sal G.; ''Interaction of p53 with prolyl isomerases: Healthy and unhealthy relationships.''; PubMed Europe PMC Scholia
33. Tian C, Xing G, Xie P, Lu K, Nie J, Wang J, Li L, Gao M, Zhang L, He F.; ''KRAB-type zinc-finger protein Apak specifically regulates p53-dependent apoptosis.''; PubMed Europe PMC Scholia
34. Li CQ, Robles AI, Hanigan CL, Hofseth LJ, Trudel LJ, Harris CC, Wogan GN.; ''Apoptotic signaling pathways induced by nitric oxide in human lymphoblastoid cells expressing wild-type or mutant p53.''; PubMed Europe PMC Scholia
35. Riley T, Sontag E, Chen P, Levine A.; ''Transcriptional control of human p53-regulated genes.''; PubMed Europe PMC Scholia
36. Park WR, Nakamura Y.; ''p53CSV, a novel p53-inducible gene involved in the p53-dependent cell-survival pathway.''; PubMed Europe PMC Scholia
37. Fischer U, Jänicke RU, Schulze-Osthoff K.; ''Many cuts to ruin: a comprehensive update of caspase substrates.''; PubMed Europe PMC Scholia
38. Fei P, Wang W, Kim SH, Wang S, Burns TF, Sax JK, Buzzai M, Dicker DT, McKenna WG, Bernhard EJ, El-Deiry WS.; ''Bnip3L is induced by p53 under hypoxia, and its knockdown promotes tumor growth.''; PubMed Europe PMC Scholia
39. Phan RT, Dalla-Favera R.; ''The BCL6 proto-oncogene suppresses p53 expression in germinal-centre B cells.''; PubMed Europe PMC Scholia
40. Schroder K, Tschopp J.; ''The inflammasomes.''; PubMed Europe PMC Scholia
41. Kurz T, Terman A, Gustafsson B, Brunk UT.; ''Lysosomes in iron metabolism, ageing and apoptosis.''; PubMed Europe PMC Scholia
42. Lespagnol A, Duflaut D, Beekman C, Blanc L, Fiucci G, Marine JC, Vidal M, Amson R, Telerman A.; ''Exosome secretion, including the DNA damage-induced p53-dependent secretory pathway, is severely compromised in TSAP6/Steap3-null mice.''; PubMed Europe PMC Scholia
43. Liu X, Yue P, Khuri FR, Sun SY.; ''Decoy receptor 2 (DcR2) is a p53 target gene and regulates chemosensitivity.''; PubMed Europe PMC Scholia
44. Bergamaschi D, Samuels Y, Jin B, Duraisingham S, Crook T, Lu X.; ''ASPP1 and ASPP2: common activators of p53 family members.''; PubMed Europe PMC Scholia
45. Saito M, Novak U, Piovan E, Basso K, Sumazin P, Schneider C, Crespo M, Shen Q, Bhagat G, Califano A, Chadburn A, Pasqualucci L, Dalla-Favera R.; ''BCL6 suppression of BCL2 via Miz1 and its disruption in diffuse large B cell lymphoma.''; PubMed Europe PMC Scholia
46. Hoeflich A, Reisinger R, Lahm H, Kiess W, Blum WF, Kolb HJ, Weber MM, Wolf E.; ''Insulin-like growth factor-binding protein 2 in tumorigenesis: protector or promoter?''; PubMed Europe PMC Scholia
47. Nematollahi LA, Garza-Garcia A, Bechara C, Esposito D, Morgner N, Robinson CV, Driscoll PC.; ''Flexible stoichiometry and asymmetry of the PIDDosome core complex by heteronuclear NMR spectroscopy and mass spectrometry.''; PubMed Europe PMC Scholia
48. Tomasini R, Samir AA, Carrier A, Isnardon D, Cecchinelli B, Soddu S, Malissen B, Dagorn JC, Iovanna JL, Dusetti NJ.; ''TP53INP1s and homeodomain-interacting protein kinase-2 (HIPK2) are partners in regulating p53 activity.''; PubMed Europe PMC Scholia
49. Tinel A, Tschopp J.; ''The PIDDosome, a protein complex implicated in activation of caspase-2 in response to genotoxic stress.''; PubMed Europe PMC Scholia
50. Miyashita T, Reed JC.; ''Tumor suppressor p53 is a direct transcriptional activator of the human bax gene.''; PubMed Europe PMC Scholia
51. Yuan L, Tian C, Wang H, Song S, Li D, Xing G, Yin Y, He F, Zhang L.; ''Apak competes with p53 for direct binding to intron 1 of p53AIP1 to regulate apoptosis.''; PubMed Europe PMC Scholia
52. Ingermann AR, Yang YF, Han J, Mikami A, Garza AE, Mohanraj L, Fan L, Idowu M, Ware JL, Kim HS, Lee DY, Oh Y.; ''Identification of a novel cell death receptor mediating IGFBP-3-induced anti-tumor effects in breast and prostate cancer.''; PubMed Europe PMC Scholia
53. Farnsworth CC, Seabra MC, Ericsson LH, Gelb MH, Glomset JA.; ''Rab geranylgeranyl transferase catalyzes the geranylgeranylation of adjacent cysteines in the small GTPases Rab1A, Rab3A, and Rab5A.''; PubMed Europe PMC Scholia
54. Wang X.; ''The expanding role of mitochondria in apoptosis.''; PubMed Europe PMC Scholia
55. Ihrie RA, Reczek E, Horner JS, Khachatrian L, Sage J, Jacks T, Attardi LD.; ''Perp is a mediator of p53-dependent apoptosis in diverse cell types.''; PubMed Europe PMC Scholia
56. Kruiswijk F, Labuschagne CF, Vousden KH.; ''p53 in survival, death and metabolic health: a lifeguard with a licence to kill.''; PubMed Europe PMC Scholia
57. Hamacher-Brady A, Choe SC, Krijnse-Locker J, Brady NR.; ''Intramitochondrial recruitment of endolysosomes mediates Smac degradation and constitutes a novel intrinsic apoptosis antagonizing function of XIAP E3 ligase.''; PubMed Europe PMC Scholia
58. Miliara X, Garnett JA, Tatsuta T, Abid Ali F, Baldie H, Pérez-Dorado I, Simpson P, Yague E, Langer T, Matthews S.; ''Structural insight into the TRIAP1/PRELI-like domain family of mitochondrial phospholipid transfer complexes.''; PubMed Europe PMC Scholia
59. Kruse JP, Gu W.; ''Modes of p53 regulation.''; PubMed Europe PMC Scholia
60. Samuels-Lev Y, O'Connor DJ, Bergamaschi D, Trigiante G, Hsieh JK, Zhong S, Campargue I, Naumovski L, Crook T, Lu X.; ''ASPP proteins specifically stimulate the apoptotic function of p53.''; PubMed Europe PMC Scholia
61. Taira N, Nihira K, Yamaguchi T, Miki Y, Yoshida K.; ''DYRK2 is targeted to the nucleus and controls p53 via Ser46 phosphorylation in the apoptotic response to DNA damage.''; PubMed Europe PMC Scholia
62. Salvesen GS, Duckett CS.; ''IAP proteins: blocking the road to death's door.''; PubMed Europe PMC Scholia
63. Sax JK, Fei P, Murphy ME, Bernhard E, Korsmeyer SJ, El-Deiry WS.; ''BID regulation by p53 contributes to chemosensitivity.''; PubMed Europe PMC Scholia
64. Patel S, George R, Autore F, Fraternali F, Ladbury JE, Nikolova PV.; ''Molecular interactions of ASPP1 and ASPP2 with the p53 protein family and the apoptotic promoters PUMA and Bax.''; PubMed Europe PMC Scholia
65. Hoffman WH, Biade S, Zilfou JT, Chen J, Murphy M.; ''Transcriptional repression of the anti-apoptotic survivin gene by wild type p53.''; PubMed Europe PMC Scholia
66. Thomä NH, Iakovenko A, Goody RS, Alexandrov K.; ''Phosphoisoprenoids modulate association of Rab geranylgeranyltransferase with REP-1.''; PubMed Europe PMC Scholia
67. Song Y, Cao L.; ''N-myc downstream-regulated gene 1: Diverse and complicated functions in human hepatocellular carcinoma (Review).''; PubMed Europe PMC Scholia
68. Giam M, Okamoto T, Mintern JD, Strasser A, Bouillet P.; ''Bcl-2 family member Bcl-G is not a proapoptotic protein.''; PubMed Europe PMC Scholia
69. Holly J, Perks C.; ''The role of insulin-like growth factor binding proteins.''; PubMed Europe PMC Scholia
70. Ruiz de Almodóvar C, Ruiz-Ruiz C, Rodríguez A, Ortiz-Ferrón G, Redondo JM, López-Rivas A.; ''Tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) decoy receptor TRAIL-R3 is up-regulated by p53 in breast tumor cells through a mechanism involving an intronic p53-binding site.''; PubMed Europe PMC Scholia
71. Murray-Zmijewski F, Slee EA, Lu X.; ''A complex barcode underlies the heterogeneous response of p53 to stress.''; PubMed Europe PMC Scholia
72. Attardi LD, Reczek EE, Cosmas C, Demicco EG, McCurrach ME, Lowe SW, Jacks T.; ''PERP, an apoptosis-associated target of p53, is a novel member of the PMP-22/gas3 family.''; PubMed Europe PMC Scholia
73. Wilson AM, Morquette B, Abdouh M, Unsain N, Barker PA, Feinstein E, Bernier G, Di Polo A.; ''ASPP1/2 regulate p53-dependent death of retinal ganglion cells through PUMA and Fas/CD95 activation in vivo.''; PubMed Europe PMC Scholia
74. Hower V, Mendes P, Torti FM, Laubenbacher R, Akman S, Shulaev V, Torti SV.; ''A general map of iron metabolism and tissue-specific subnetworks.''; PubMed Europe PMC Scholia
75. Jen KY, Cheung VG.; ''Identification of novel p53 target genes in ionizing radiation response.''; PubMed Europe PMC Scholia
76. Okamura S, Arakawa H, Tanaka T, Nakanishi H, Ng CC, Taya Y, Monden M, Nakamura Y.; ''p53DINP1, a p53-inducible gene, regulates p53-dependent apoptosis.''; PubMed Europe PMC Scholia
77. Jain N, Gupta S, Sudhakar Ch, Radha V, Swarup G.; ''Role of p73 in regulating human caspase-1 gene transcription induced by interferon-{gamma} and cisplatin.''; PubMed Europe PMC Scholia
78. Firth SM, Baxter RC.; ''Cellular actions of the insulin-like growth factor binding proteins.''; PubMed Europe PMC Scholia
79. Rikhof B, Corn PG, El-Deiry WS.; ''Caspase 10 levels are increased following DNA damage in a p53-dependent manner.''; PubMed Europe PMC Scholia
80. Buckbinder L, Talbott R, Velasco-Miguel S, Takenaka I, Faha B, Seizinger BR, Kley N.; ''Induction of the growth inhibitor IGF-binding protein 3 by p53.''; PubMed Europe PMC Scholia
81. Seabra MC, Goldstein JL, Südhof TC, Brown MS.; ''Rab geranylgeranyl transferase. A multisubunit enzyme that prenylates GTP-binding proteins terminating in Cys-X-Cys or Cys-Cys.''; PubMed Europe PMC Scholia
82. Oppermann U.; ''Carbonyl reductases: the complex relationships of mammalian carbonyl- and quinone-reducing enzymes and their role in physiology.''; PubMed Europe PMC Scholia
83. Stein S, Thomas EK, Herzog B, Westfall MD, Rocheleau JV, Jackson RS, Wang M, Liang P.; ''NDRG1 is necessary for p53-dependent apoptosis.''; PubMed Europe PMC Scholia
84. Sprick MR, Rieser E, Stahl H, Grosse-Wilde A, Weigand MA, Walczak H.; ''Caspase-10 is recruited to and activated at the native TRAIL and CD95 death-inducing signalling complexes in a FADD-dependent manner but can not functionally substitute caspase-8.''; PubMed Europe PMC Scholia
85. Saelens X, Festjens N, Vande Walle L, van Gurp M, van Loo G, Vandenabeele P.; ''Toxic proteins released from mitochondria in cell death.''; PubMed Europe PMC Scholia
86. Poyet JL, Srinivasula SM, Tnani M, Razmara M, Fernandes-Alnemri T, Alnemri ES.; ''Identification of Ipaf, a human caspase-1-activating protein related to Apaf-1.''; PubMed Europe PMC Scholia
87. Li Y, Zhao Y, Hu J, Xiao J, Qu L, Wang Z, Ma D, Chen Y.; ''A novel ER-localized transmembrane protein, EMC6, interacts with RAB5A and regulates cell autophagy.''; PubMed Europe PMC Scholia
88. Margalit O, Amram H, Amariglio N, Simon AJ, Shaklai S, Granot G, Minsky N, Shimoni A, Harmelin A, Givol D, Shohat M, Oren M, Rechavi G.; ''BCL6 is regulated by p53 through a response element frequently disrupted in B-cell non-Hodgkin lymphoma.''; PubMed Europe PMC Scholia
89. Marzec KA, Lin MZ, Martin JL, Baxter RC.; ''Involvement of p53 in insulin-like growth factor binding protein-3 regulation in the breast cancer cell response to DNA damage.''; PubMed Europe PMC Scholia
90. Wang S, El-Deiry WS.; ''TRAIL and apoptosis induction by TNF-family death receptors.''; PubMed Europe PMC Scholia
91. Cerretti DP, Kozlosky CJ, Mosley B, Nelson N, Van Ness K, Greenstreet TA, March CJ, Kronheim SR, Druck T, Cannizzaro LA.; ''Molecular cloning of the interleukin-1 beta converting enzyme.''; PubMed Europe PMC Scholia
92. Passer BJ, Nancy-Portebois V, Amzallag N, Prieur S, Cans C, Roborel de Climens A, Fiucci G, Bouvard V, Tuynder M, Susini L, Morchoisne S, Crible V, Lespagnol A, Dausset J, Oren M, Amson R, Telerman A.; ''The p53-inducible TSAP6 gene product regulates apoptosis and the cell cycle and interacts with Nix and the Myt1 kinase.''; PubMed Europe PMC Scholia
93. Ihrie RA, Marques MR, Nguyen BT, Horner JS, Papazoglu C, Bronson RT, Mills AA, Attardi LD.; ''Perp is a p63-regulated gene essential for epithelial integrity.''; PubMed Europe PMC Scholia
94. Meek DW, Anderson CW.; ''Posttranslational modification of p53: cooperative integrators of function.''; PubMed Europe PMC Scholia
95. Baron RA, Seabra MC.; ''Rab geranylgeranylation occurs preferentially via the pre-formed REP-RGGT complex and is regulated by geranylgeranyl pyrophosphate.''; PubMed Europe PMC Scholia
96. Lin Y, Ma W, Benchimol S.; ''Pidd, a new death-domain-containing protein, is induced by p53 and promotes apoptosis.''; PubMed Europe PMC Scholia
97. Zhang AH, Rao JN, Zou T, Liu L, Marasa BS, Xiao L, Chen J, Turner DJ, Wang JY.; ''p53-dependent NDRG1 expression induces inhibition of intestinal epithelial cell proliferation but not apoptosis after polyamine depletion.''; PubMed Europe PMC Scholia
98. Guo B, Godzik A, Reed JC.; ''Bcl-G, a novel pro-apoptotic member of the Bcl-2 family.''; PubMed Europe PMC Scholia
99. Wang J, Chun HJ, Wong W, Spencer DM, Lenardo MJ.; ''Caspase-10 is an initiator caspase in death receptor signaling.''; PubMed Europe PMC Scholia
100. Oda K, Arakawa H, Tanaka T, Matsuda K, Tanikawa C, Mori T, Nishimori H, Tamai K, Tokino T, Nakamura Y, Taya Y.; ''p53AIP1, a potential mediator of p53-dependent apoptosis, and its regulation by Ser-46-phosphorylated p53.''; PubMed Europe PMC Scholia
101. Schilling T, Schleithoff ES, Kairat A, Melino G, Stremmel W, Oren M, Krammer PH, Müller M.; ''Active transcription of the human FAS/CD95/TNFRSF6 gene involves the p53 family.''; PubMed Europe PMC Scholia
102. Lackner MR, Kindt RM, Carroll PM, Brown K, Cancilla MR, Chen C, de Silva H, Franke Y, Guan B, Heuer T, Hung T, Keegan K, Lee JM, Manne V, O'Brien C, Parry D, Perez-Villar JJ, Reddy RK, Xiao H, Zhan H, Cockett M, Plowman G, Fitzgerald K, Costa M, Ross-Macdonald P.; ''Chemical genetics identifies Rab geranylgeranyl transferase as an apoptotic target of farnesyl transferase inhibitors.''; PubMed Europe PMC Scholia
103. MacLachlan TK, El-Deiry WS.; ''Apoptotic threshold is lowered by p53 transactivation of caspase-6.''; PubMed Europe PMC Scholia
104. Hengartner MO.; ''The biochemistry of apoptosis.''; PubMed Europe PMC Scholia
105. Oda E, Ohki R, Murasawa H, Nemoto J, Shibue T, Yamashita T, Tokino T, Taniguchi T, Tanaka N.; ''Noxa, a BH3-only member of the Bcl-2 family and candidate mediator of p53-induced apoptosis.''; PubMed Europe PMC Scholia

History

External references

DataNodes

Name	Type	Database reference	Comment
(p-S15,S20-TP53,TP63):PERP Gene	Complex	R-HSA-6800835 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):BAX Gene	Complex	R-HSA-3700978 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):BBC3 Gene	Complex	R-HSA-4331345 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):FAS Gene	Complex	R-HSA-6799810 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):TP53I3 Gene	Complex	R-HSA-6799461 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2)	Complex	R-HSA-6799788 (Reactome)
(p-S15,S20-TP53,TP63,TP73):CASP1 Gene	Complex	R-HSA-6798078 (Reactome)
1,2-Naphthoquinone	Metabolite	CHEBI:34055 (ChEBI)
ADP	Metabolite	CHEBI:456216 (ChEBI)
AIFM2 Gene	Protein	ENSG00000042286 (Ensembl)
AIFM2 Gene	GeneProduct	ENSG00000042286 (Ensembl)
AIFM2	Protein	Q9BRQ8 (Uniprot-TrEMBL)
APAF1 gene	Protein	ENSG00000120868 (Ensembl)
APAF1 gene	GeneProduct	ENSG00000120868 (Ensembl)
APAF1	Protein	O14727 (Uniprot-TrEMBL)
ATP	Metabolite	CHEBI:30616 (ChEBI)
Apoptotic execution phase	Pathway	R-HSA-75153 (Reactome)	In the execution phase of apoptosis, effector caspases cleave vital cellular proteins leading to the morphological changes that characterize apoptosis. These changes include destruction of the nucleus and other organelles, DNA fragmentation, chromatin condensation, cell shrinkage and cell detachment and membrane blebbing (reviewed in Fischer et al., 2003).
BAX gene	Protein	ENSG00000087088 (Ensembl)
BAX gene	GeneProduct	ENSG00000087088 (Ensembl)
BAX	Protein	Q07812 (Uniprot-TrEMBL)
BBC3 gene	Protein	ENSG00000105327 (Ensembl)
BBC3 gene	GeneProduct	ENSG00000105327 (Ensembl)
BBC3	Protein	Q9BXH1 (Uniprot-TrEMBL)
BCL2L14 Gene	Protein	ENSG00000121380 (Ensembl)
BCL2L14 Gene	GeneProduct	ENSG00000121380 (Ensembl)
BCL2L14	Protein	Q9BZR8 (Uniprot-TrEMBL)
BCL6 gene	Protein	ENSG00000113916 (Ensembl)
BCL6 gene	GeneProduct	ENSG00000113916 (Ensembl)
BCL6	Protein	P41182 (Uniprot-TrEMBL)
BID Gene	Protein	ENSG00000015475 (Ensembl)
BID Gene	GeneProduct	ENSG00000015475 (Ensembl)
BID(1-195)	Protein	P55957 (Uniprot-TrEMBL)
BIRC5 Gene	Protein	ENSG00000089685 (Ensembl)
BIRC5 Gene	GeneProduct	ENSG00000089685 (Ensembl)
BIRC5	Protein	O15392 (Uniprot-TrEMBL)
BNIP3L Gene	Protein	ENSG00000104765 (Ensembl)
BNIP3L Gene	GeneProduct	ENSG00000104765 (Ensembl)
BNIP3L	Protein	O60238 (Uniprot-TrEMBL)
BNIP3L	Protein	O60238 (Uniprot-TrEMBL)
CASP1 Gene	Protein	ENSG00000137752 (Ensembl)
CASP1 Gene	GeneProduct	ENSG00000137752 (Ensembl)
CASP1(1-404)	Protein	P29466 (Uniprot-TrEMBL)
CASP10 Gene	Protein	ENSG00000003400 (Ensembl)
CASP10 Gene	GeneProduct	ENSG00000003400 (Ensembl)
CASP10(1-521)	Protein	Q92851 (Uniprot-TrEMBL)
CASP2(170-325)	Protein	P42575 (Uniprot-TrEMBL)
CASP2(2-452)	Protein	P42575 (Uniprot-TrEMBL)
CASP2(2-452)	Protein	P42575 (Uniprot-TrEMBL)
CASP2(348-452)	Protein	P42575 (Uniprot-TrEMBL)
CASP6 (1-293)	Protein	P55212 (Uniprot-TrEMBL)
CASP6 Gene	Protein	ENSG00000138794 (Ensembl)
CASP6 Gene	GeneProduct	ENSG00000138794 (Ensembl)
CHM	Protein	P24386 (Uniprot-TrEMBL)
CHM	Protein	P24386 (Uniprot-TrEMBL)
CRADD	Protein	P78560 (Uniprot-TrEMBL)
CRADD	Protein	P78560 (Uniprot-TrEMBL)
CREBBP	Protein	Q92793 (Uniprot-TrEMBL)
CREBBP	Protein	Q92793 (Uniprot-TrEMBL)
FAS Gene	Protein	ENSG00000026103 (Ensembl)
FAS Gene	GeneProduct	ENSG00000026103 (Ensembl)
FAS	Protein	P25445 (Uniprot-TrEMBL)
FasL/ CD95L signaling	Pathway	R-HSA-75157 (Reactome)	The Fas family of cell surface receptors initiate the apototic pathway through interaction with the external ligand, FasL. The cytoplasmic domain of Fas interacts with a number of molecules in the transduction of the external signal to the cytoplasmic side of the cell membrane. The most notable cytoplasmic domain is the Death Domain (DD) that is involved in recruiting the FAS-associating death domain-containing protein (FADD). This interaction drives downstream events.
H+	Metabolite	CHEBI:15378 (ChEBI)
IGFBP3 Gene	Protein	ENSG00000146674 (Ensembl)
IGFBP3 Gene	GeneProduct	ENSG00000146674 (Ensembl)
IGFBP3	Protein	P17936 (Uniprot-TrEMBL)
IGFBP3:TMEM219	Complex	R-HSA-6800024 (Reactome)
IGFBP3	Protein	P17936 (Uniprot-TrEMBL)
Innate Immune System	Pathway	R-HSA-168249 (Reactome)	Innate immunity encompases the nonspecific part of immunity tha are part of an individual's natural biologic makeup
Interleukin-1 processing	Pathway	R-HSA-448706 (Reactome)	The IL-1 family of cytokines that interact with the Type 1 IL-1R include IL-1α (IL1A), IL-1β (IL1B) and the IL-1 receptor antagonist protein (IL1RAP). IL1RAP is synthesized with a signal peptide and secreted as a mature protein via the classical secretory pathway. IL1A and IL1B are synthesised as cytoplasmic precursors (pro-IL1A and pro-IL1B) in activated cells. They have no signal sequence, precluding secretion via the classical ER-Golgi route (Rubartelli et al. 1990). Processing of pro-IL1B to the active form requires caspase-1 (Thornberry et al. 1992), which is itself activated by a molecular scaffold termed the inflammasome (Martinon et al. 2002). Processing and release of IL1B are thought to be closely linked, because mature IL1B is only seen inside inflammatory cells just prior to release (Brough et al. 2003). It has been reported that in monocytes a fraction of cellular IL1B is released by the regulated secretion of late endosomes and early lysosomes, and that this may represent a cellular compartment where caspase-1 processing of pro-IL1B takes place (Andrei et al. 1999). Shedding of microvesicles from the plasma membrane has also been proposed as a mechanism of secretion (MacKenzie et al. 2001). These proposals superceded previous models in which non-specific release due to cell lysis and passage through a plasma membrane pore were considered. However, there is evidence in the literature that supports all of these mechanisms and there is still controversy over how IL1B exits from cells (Brough & Rothwell 2007). A calpain-like potease has been reported to be important for the processing of pro-IL1A, but much less is known about how IL1A is released from cells and what specific roles it plays in biology.
Intrinsic Pathway for Apoptosis	Pathway	R-HSA-109606 (Reactome)	The intrinsic (Bcl-2 inhibitable or mitochondrial) pathway of apoptosis functions in response to various types of intracellular stress including growth factor withdrawal, DNA damage, unfolding stresses in the endoplasmic reticulum and death receptor stimulation. Following the reception of stress signals, proapoptotic BCL-2 family proteins are activated and subsequently interact with and inactivate antiapoptotic BCL-2 proteins. This interaction leads to the destabilization of the mitochondrial membrane and release of apoptotic factors. These factors induce the caspase proteolytic cascade, chromatin condensation, and DNA fragmentation, ultimately leading to cell death. The key players in the Intrinsic pathway are the Bcl-2 family of proteins that are critical death regulators residing immediately upstream of mitochondria. The Bcl-2 family consists of both anti- and proapoptotic members that possess conserved alpha-helices with sequence conservation clustered in BCL-2 Homology (BH) domains. Proapoptotic members are organized as follows: 1. "Multidomain" BAX family proteins such as BAX, BAK etc. that display sequence conservation in their BH1-3 regions. These proteins act downstream in mitochondrial disruption. 2. "BH3-only" proteins such as BID,BAD, NOXA, PUMA,BIM, and BMF have only the short BH3 motif. These act upstream in the pathway, detecting developmental death cues or intracellular damage. Anti-apoptotic members like Bcl-2, Bcl-XL and their relatives exhibit homology in all segments BH1-4. One of the critical functions of BCL-2/BCL-XL proteins is to maintain the integrity of the mitochondrial outer membrane.
Iron uptake and transport	Pathway	R-HSA-917937 (Reactome)	The transport of iron between cells is mediated by transferrin. However, iron can also enter and leave cells not only by itself, but also in the form of heme and siderophores. When entering the cell via the main path (by transferrin endocytosis), its goal is not the (still elusive) chelated iron pool in the cytosol nor the lysosomes but the mitochondria, where heme is synthesized and iron-sulfur clusters are assembled (Kurz et al,2008, Hower et al 2009, Richardson et al 2010).
NADP+	Metabolite	CHEBI:18009 (ChEBI)
NADPH	Metabolite	CHEBI:16474 (ChEBI)
NDRG1 Gene	Protein	ENSG00000104419 (Ensembl)
NDRG1 Gene	GeneProduct	ENSG00000104419 (Ensembl)
NDRG1	Protein	Q92597 (Uniprot-TrEMBL)
NLRC4 Gene	Protein	ENSG00000091106 (Ensembl)
NLRC4 Gene	GeneProduct	ENSG00000091106 (Ensembl)
NLRC4	Protein	Q9NPP4 (Uniprot-TrEMBL)
O2.-	Metabolite	CHEBI:18421 (ChEBI)
O2	Metabolite	CHEBI:15379 (ChEBI)
PA	Metabolite	CHEBI:16337 (ChEBI)
PERP Gene	Protein	ENSG00000112378 (Ensembl)
PERP Gene	GeneProduct	ENSG00000112378 (Ensembl)
PERP	Protein	Q96FX8 (Uniprot-TrEMBL)
PIDD1 Gene	Protein	ENSG00000177595 (Ensembl)
PIDD1 Gene	GeneProduct	ENSG00000177595 (Ensembl)
PIDD1	Protein	Q9HB75 (Uniprot-TrEMBL)
PIDDosome:CASP2(2-452)	Complex	R-HSA-6800803 (Reactome)
PIDDosome	Complex	R-HSA-6800782 (Reactome)
PMAIP1 Gene	Protein	ENSG00000141682 (Ensembl)
PMAIP1 Gene	GeneProduct	ENSG00000141682 (Ensembl)
PMAIP1	Protein	Q13794 (Uniprot-TrEMBL)
PPP1R13B	Protein	Q96KQ4 (Uniprot-TrEMBL)
PRELID1	Protein	Q9Y255 (Uniprot-TrEMBL)
PRELID1, PRELID3A	Complex	R-HSA-8870822 (Reactome)
PRELID3A	Protein	Q96N28 (Uniprot-TrEMBL)
RABGGTA Gene	Protein	ENSG00000100949 (Ensembl)
RABGGTA Gene	GeneProduct	ENSG00000100949 (Ensembl)
RABGGTA	Protein	Q92696 (Uniprot-TrEMBL)
RABGGTA	Protein	Q92696 (Uniprot-TrEMBL)
RABGGTB	Protein	P53611 (Uniprot-TrEMBL)
RABGGTB	Protein	P53611 (Uniprot-TrEMBL)
RGGT:CHM	Complex	R-HSA-6801111 (Reactome)
RGGT	Complex	R-HSA-6801105 (Reactome)
Regulation of Insulin-like Growth Factor (IGF) transport and uptake by Insulin-like Growth Factor Binding Proteins (IGFBPs)	Pathway	R-HSA-381426 (Reactome)	The family of Insulin like Growth Factor Binding Proteins (IGFBPs) share 50% amino acid identity with conserved N terminal and C terminal regions responsible for binding Insulin like Growth Factors I and II (IGF I and IGF II). Most circulating IGFs are in complexes with IGFBPs, which are believed to increase the residence of IGFs in the body, modulate availability of IGFs to target receptors for IGFs, reduce insulin like effects of IGFs, and act as signaling molecules independently of IGFs. About 75% of circulating IGFs are in 1500 220 KDa complexes with IGFBP3 and ALS. Such complexes are too large to pass the endothelial barrier. The remaining 20 25% of IGFs are bound to other IGFBPs in 40 50 KDa complexes. IGFs are released from IGF:IGFBP complexes by proteolysis of the IGFBP. IGFs become active after release, however IGFs may also have activity when still bound to some IGFBPs. IGFBP1 is enriched in amniotic fluid and is produced in the liver under control of insulin (insulin suppresses production). IGFBP1 binding stimulates IGF function. It is unknown which if any protease degrades IGFBP1. IGFBP2 is enriched in cerebrospinal fluid; its binding inhibits IGF function. IGFBP2 is not significantly degraded in circulation. IGFB3, which binds most IGF in the body is enriched in follicular fluid and found in many other tissues. IGFBP 3 may be cleaved by plasmin, thrombin, Prostate specific Antigen (PSA, KLK3), Matrix Metalloprotease-1 (MMP1), and Matrix Metalloprotease-2 (MMP2). IGFBP3 also binds extracellular matrix and binding lowers its affinity for IGFs. IGFBP3 binding stimulates the effects of IGFs. IGFBP4 acts to inhibit IGF function and is cleaved by Pregnancy associated Plasma Protein A (PAPPA) to release IGF. IGFBP5 is enriched in bone matrix; its binding stimulates IGF function. IGFBP5 is cleaved by Pregnancy Associated Plasma Protein A2 (PAPPA2), ADAM9, complement C1s from smooth muscle, and thrombin. Only the cleavage site for PAPPA2 is known. IGFBP6 is enriched in cerebrospinal fluid. It is unknown which if any protease degrades IGFBP6.
Regulation of TP53 Activity	Pathway	R-HSA-5633007 (Reactome)	Protein stability and transcriptional activity of TP53 (p53) tumor suppressor are regulated by post-translational modifications that include ubiquitination, phosphorylation, acetylation, methylation, sumoylation and prolyl-isomerization (Kruse and Gu 2009, Meek and Anderson 2009, Santiago et al. 2013, Mantovani et al. 2015). In addition to post-translational modifications, the activity of TP53 is also regulated by binding of transcription co-factors. In unstressed cells, TP53 protein levels are low due to MDM2-mediated ubiquitination of TP53, which triggers proteasome-mediated degradation. In response to stress, TP53 undergoes stabilizing phosphorylation, mainly at serine residues S15 and S20. Several different kinases can phosphorylate TP53 at these sites, but the main S15 kinases are considered to be ATM and ATR, while the main S20 kinases are considered to be CHEK2 and CHEK1. Additional phosphorylation of TP53 at serine residue S46 promotes transcription of pro-apoptotic, rather than cell cycle arrest genes. Acetylation mainly has a positive impact on transcriptional activity of TP53, while methylation can both positively and negatively regulate TP53. Some posttranslational modifications regulate interaction of TP53 with transcriptional co-factors, some of which are themselves transcriptional targets of TP53. For review of the complex network of TP53 regulation, please refer to Kruse and Gu 2009, and Meek and Anderson 2009.
STEAP3 Gene	Protein	ENSG00000115107 (Ensembl)
STEAP3 Gene	GeneProduct	ENSG00000115107 (Ensembl)
STEAP3	Protein	Q658P3 (Uniprot-TrEMBL)
STEAP3:BNIP3L	Complex	R-HSA-6801198 (Reactome)
STEAP3	Protein	Q658P3 (Uniprot-TrEMBL)
TMEM219	Protein	Q86XT9 (Uniprot-TrEMBL)
TMEM219	Protein	Q86XT9 (Uniprot-TrEMBL)
TNFRSF10A Gene	Protein	ENSG00000104689 (Ensembl)
TNFRSF10A	Protein	O00220 (Uniprot-TrEMBL)
TNFRSF10A, TNFRSF10B, TNFRSF10C, TNFRSF10D	Complex	R-HSA-6801323 (Reactome)
TNFRSF10A,TNFRSF10B,TNFRSF10C,TNFRSF10D Genes	Complex	R-HSA-5633424 (Reactome)
TNFRSF10B Gene	Protein	ENSG00000120889 (Ensembl)
TNFRSF10B	Protein	O14763 (Uniprot-TrEMBL)
TNFRSF10C Gene	Protein	ENSG00000173535 (Ensembl)
TNFRSF10C	Protein	O14798 (Uniprot-TrEMBL)
TNFRSF10D Gene	Protein	ENSG00000173530 (Ensembl)
TNFRSF10D	Protein	Q9UBN6 (Uniprot-TrEMBL)
TP53AIP1 Gene	Protein	ENSG00000120471 (Ensembl)
TP53AIP1 Gene	GeneProduct	ENSG00000120471 (Ensembl)
TP53AIP1	Protein	Q9HCN2 (Uniprot-TrEMBL)
TP53BP2	Protein	Q13625 (Uniprot-TrEMBL)
TP53I3 Dimer	Complex	R-HSA-6799448 (Reactome)
TP53I3 Gene	Protein	ENSG00000115129 (Ensembl)
TP53I3 Gene	GeneProduct	ENSG00000115129 (Ensembl)
TP53I3	Protein	Q53FA7 (Uniprot-TrEMBL)
TP53I3	Protein	Q53FA7 (Uniprot-TrEMBL)
TP53INP1 Gene	Protein	ENSG00000164938 (Ensembl)
TP53INP1 Gene	GeneProduct	ENSG00000164938 (Ensembl)
TP53INP1	Protein	Q96A56 (Uniprot-TrEMBL)
TP63	Protein	Q9H3D4 (Uniprot-TrEMBL)
TP73	Protein	O15350 (Uniprot-TrEMBL)
TRAIL signaling	Pathway	R-HSA-75158 (Reactome)	Tumor necrosis factor-related apoptosis-inducing ligand or Apo 2 ligand (TRAIL/Apo2L) is a member of the tumor necrosis factor (TNF) family. This group of apoptosis induction pathways all work through protein interactions mediated by the intracellular death domain (DD), encoded within the cytoplasmic domain of the receptor. TRAIL selectively induces apoptosis through its interaction with the Fas-associated death domain protein (FADD) and caspase-8/10 (Wang S & el-Deiry WS 2003; Sprick MR et al. 2002). TRAIL and its receptors, TRAIL-R1 and TRAIL-R2, were shown to be rapidly endocytosed via clathrin-dependent and -independent manner in human Burkitt's lymphoma B cells (BJAB) (Kohlhaas SL et al. 2007). However, FADD and caspase-8 were able to bind TRAIL-R1/R2 in TRAIL-stimulated BJAB cells at 4oC (at which membrane trafficking is inhibited), suggesting that the endocytosis was not required for an assembly of the functional TRAIL DISC complex. Moreover, blocking of clathrin-dependent endocytosis did not interfere with the capacity of TRAIL to promote apoptosis (Kohlhaas SL et al. 2007).
TRIAP1 Gene	Protein	ENSG00000170855 (Ensembl)
TRIAP1 Gene	GeneProduct	ENSG00000170855 (Ensembl)
TRIAP1	Protein	O43715 (Uniprot-TrEMBL)
TRIAP1:PRELID1, PRELID3A	Complex	R-HSA-6801235 (Reactome)
TRIAP1	Protein	O43715 (Uniprot-TrEMBL)
ZNF420	Protein	Q8TAQ5 (Uniprot-TrEMBL)
ZNF420:TP53AIP1 Gene	Complex	R-HSA-6798631 (Reactome)
ZNF420	Protein	Q8TAQ5 (Uniprot-TrEMBL)
p-S15,S20,S46-TP53 Tetramer:TP53AIP1 Gene	Complex	R-HSA-6798606 (Reactome)
p-S15,S20,S46-TP53 Tetramer	Complex	R-HSA-6798371 (Reactome)
p-S15,S20,S46-TP53	Protein	P04637 (Uniprot-TrEMBL)
p-S15,S20-TP53 Tetramer:AIFM2 Gene	Complex	R-HSA-6791298 (Reactome)
p-S15,S20-TP53 Tetramer:APAF1 Gene	Complex	R-HSA-6791350 (Reactome)
p-S15,S20-TP53 Tetramer:BCL2L14 Gene	Complex	R-HSA-6791328 (Reactome)
p-S15,S20-TP53 Tetramer:BCL6 Gene	Complex	R-HSA-6800252 (Reactome)
p-S15,S20-TP53 Tetramer:BID Gene	Complex	R-HSA-6791290 (Reactome)
p-S15,S20-TP53 Tetramer:BIRC5 Gene	Complex	R-HSA-6797767 (Reactome)
p-S15,S20-TP53 Tetramer:CASP10 Gene	Complex	R-HSA-6798147 (Reactome)
p-S15,S20-TP53 Tetramer:CASP6 Gene	Complex	R-HSA-6798123 (Reactome)
p-S15,S20-TP53 Tetramer:CREBBP:BNIP3L Gene	Complex	R-HSA-6797994 (Reactome)
p-S15,S20-TP53 Tetramer:IGFBP3 Gene	Complex	R-HSA-6800034 (Reactome)
p-S15,S20-TP53 Tetramer:NDRG1 Gene	Complex	R-HSA-5633301 (Reactome)
p-S15,S20-TP53 Tetramer:PIDD1 Gene	Complex	R-HSA-6800276 (Reactome)
p-S15,S20-TP53 Tetramer:PMAIP1 Gene	Complex	R-HSA-4331332 (Reactome)
p-S15,S20-TP53 Tetramer:RABGGTA Gene	Complex	R-HSA-6801088 (Reactome)
p-S15,S20-TP53 Tetramer:STEAP3 Gene	Complex	R-HSA-6801165 (Reactome)
p-S15,S20-TP53 Tetramer:TNFRSF10A,TNFRSF10B,TNFRSF10C,TNFRSF10D Genes	Complex	R-HSA-5633436 (Reactome)
p-S15,S20-TP53 Tetramer:TP53INP1 Gene	Complex	R-HSA-6799421 (Reactome)
p-S15,S20-TP53 Tetramer:TRIAP1 Gene	Complex	R-HSA-6801208 (Reactome)
p-S15,S20-TP53 Tetramer	Complex	R-HSA-3222171 (Reactome)
p-S15,S20-TP53	Protein	P04637 (Uniprot-TrEMBL)
p-S15,S20-TP53,TP63,TP73	Complex	R-HSA-6798076 (Reactome)
p-S15,S20-TP53,TP63	Complex	R-HSA-6800828 (Reactome)
p-S15,S20-TP53:NLRC4 Gene	Complex	R-HSA-6801357 (Reactome)
p-S1981,Ac-K3016-ATM	Protein	Q13315 (Uniprot-TrEMBL)
p-S68-ZNF420	Protein	Q8TAQ5 (Uniprot-TrEMBL)
p-T788-PIDD1	Protein	Q9HB75 (Uniprot-TrEMBL)
p-T788-PIDD1	Protein	Q9HB75 (Uniprot-TrEMBL)
semiquinone	Metabolite	CHEBI:15817 (ChEBI)

Annotated Interactions

Source	Target	Type	Database reference	Comment
(p-S15,S20-TP53,TP63):PERP Gene		Arrow	R-HSA-6800816 (Reactome)
	(p-S15,S20-TP53,TP63):PERP Gene	Arrow	R-HSA-6800836 (Reactome)
	(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):BAX Gene	Arrow	R-HSA-3700981 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):BAX Gene		Arrow	R-HSA-3700984 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):BBC3 Gene		Arrow	R-HSA-139913 (Reactome)
	(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):BBC3 Gene	Arrow	R-HSA-4331340 (Reactome)
	(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):FAS Gene	Arrow	R-HSA-6799815 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):FAS Gene		Arrow	R-HSA-6800001 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):TP53I3 Gene		Arrow	R-HSA-6799441 (Reactome)
	(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2):TP53I3 Gene	Arrow	R-HSA-6799462 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2)			R-HSA-3700981 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2)			R-HSA-4331340 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2)			R-HSA-6799462 (Reactome)
(p-S15,S20-TP53,TP63,TP73):(PPP1R13B,TP53BP2)			R-HSA-6799815 (Reactome)
(p-S15,S20-TP53,TP63,TP73):CASP1 Gene		Arrow	R-HSA-6798081 (Reactome)
	(p-S15,S20-TP53,TP63,TP73):CASP1 Gene	Arrow	R-HSA-6798082 (Reactome)
	1,2-Naphthoquinone	Arrow	R-HSA-6799733 (Reactome)
1,2-Naphthoquinone			R-HSA-6799722 (Reactome)
	ADP	Arrow	R-HSA-6799097 (Reactome)
	ADP	Arrow	R-HSA-6800490 (Reactome)
AIFM2 Gene			R-HSA-6791302 (Reactome)
AIFM2 Gene			R-HSA-6791306 (Reactome)
	AIFM2	Arrow	R-HSA-6791306 (Reactome)
APAF1 gene			R-HSA-6791348 (Reactome)
APAF1 gene			R-HSA-6791349 (Reactome)
	APAF1	Arrow	R-HSA-6791348 (Reactome)
ATP			R-HSA-6799097 (Reactome)
ATP			R-HSA-6800490 (Reactome)
BAX gene			R-HSA-3700981 (Reactome)
BAX gene			R-HSA-3700984 (Reactome)
	BAX	Arrow	R-HSA-3700984 (Reactome)
BBC3 gene			R-HSA-139913 (Reactome)
BBC3 gene			R-HSA-4331340 (Reactome)
	BBC3	Arrow	R-HSA-139913 (Reactome)
BCL2L14 Gene			R-HSA-6791323 (Reactome)
BCL2L14 Gene			R-HSA-6791327 (Reactome)
	BCL2L14	Arrow	R-HSA-6791323 (Reactome)
BCL6 gene			R-HSA-6800250 (Reactome)
BCL6 gene			R-HSA-6800253 (Reactome)
	BCL6	Arrow	R-HSA-6800250 (Reactome)
BID Gene			R-HSA-6791285 (Reactome)
BID Gene			R-HSA-6791291 (Reactome)
	BID(1-195)	Arrow	R-HSA-6791291 (Reactome)
BIRC5 Gene			R-HSA-6797763 (Reactome)
BIRC5 Gene			R-HSA-6797766 (Reactome)
	BIRC5	Arrow	R-HSA-6797763 (Reactome)
BNIP3L Gene			R-HSA-6797993 (Reactome)
BNIP3L Gene			R-HSA-6798004 (Reactome)
	BNIP3L	Arrow	R-HSA-6798004 (Reactome)
BNIP3L			R-HSA-6801195 (Reactome)
CASP1 Gene			R-HSA-6798081 (Reactome)
CASP1 Gene			R-HSA-6798082 (Reactome)
	CASP1(1-404)	Arrow	R-HSA-6798081 (Reactome)
CASP10 Gene			R-HSA-6798138 (Reactome)
CASP10 Gene			R-HSA-6798139 (Reactome)
	CASP10(1-521)	Arrow	R-HSA-6798139 (Reactome)
	CASP2(170-325)	Arrow	R-HSA-6800797 (Reactome)
CASP2(2-452)			R-HSA-6800798 (Reactome)
	CASP2(348-452)	Arrow	R-HSA-6800797 (Reactome)
	CASP6 (1-293)	Arrow	R-HSA-6798126 (Reactome)
CASP6 Gene			R-HSA-6798126 (Reactome)
CASP6 Gene			R-HSA-6798129 (Reactome)
CHM			R-HSA-6801109 (Reactome)
CRADD			R-HSA-6800794 (Reactome)
CREBBP			R-HSA-6797993 (Reactome)
FAS Gene			R-HSA-6799815 (Reactome)
FAS Gene			R-HSA-6800001 (Reactome)
	FAS	Arrow	R-HSA-6800001 (Reactome)
H+			R-HSA-6799722 (Reactome)
IGFBP3 Gene			R-HSA-6800042 (Reactome)
IGFBP3 Gene			R-HSA-6800044 (Reactome)
	IGFBP3:TMEM219	Arrow	R-HSA-6800035 (Reactome)
	IGFBP3	Arrow	R-HSA-6800044 (Reactome)
IGFBP3			R-HSA-6800035 (Reactome)
	NADP+	Arrow	R-HSA-6799722 (Reactome)
NADPH			R-HSA-6799722 (Reactome)
NDRG1 Gene			R-HSA-5633295 (Reactome)
NDRG1 Gene			R-HSA-5633314 (Reactome)
	NDRG1	Arrow	R-HSA-5633314 (Reactome)
NLRC4 Gene			R-HSA-6801355 (Reactome)
NLRC4 Gene			R-HSA-6801415 (Reactome)
	NLRC4	Arrow	R-HSA-6801415 (Reactome)
	O2.-	Arrow	R-HSA-6799733 (Reactome)
O2			R-HSA-6799733 (Reactome)
	PA	Arrow	R-HSA-6801250 (Reactome)
PA			R-HSA-6801250 (Reactome)
PERP Gene			R-HSA-6800816 (Reactome)
PERP Gene			R-HSA-6800836 (Reactome)
	PERP	Arrow	R-HSA-6800816 (Reactome)
PIDD1 Gene			R-HSA-6800279 (Reactome)
PIDD1 Gene			R-HSA-6800396 (Reactome)
	PIDD1	Arrow	R-HSA-6800396 (Reactome)
PIDD1			R-HSA-6800490 (Reactome)
	PIDDosome:CASP2(2-452)	Arrow	R-HSA-6800798 (Reactome)
PIDDosome:CASP2(2-452)			R-HSA-6800797 (Reactome)
PIDDosome:CASP2(2-452)		mim-catalysis	R-HSA-6800797 (Reactome)
	PIDDosome	Arrow	R-HSA-6800794 (Reactome)
	PIDDosome	Arrow	R-HSA-6800797 (Reactome)
PIDDosome			R-HSA-6800798 (Reactome)
PMAIP1 Gene			R-HSA-140214 (Reactome)
PMAIP1 Gene			R-HSA-4331331 (Reactome)
	PMAIP1	Arrow	R-HSA-140214 (Reactome)
PRELID1, PRELID3A			R-HSA-6801242 (Reactome)
			R-HSA-139913 (Reactome)	TP53 (p53) stimulates the transcription of BBC3 (PUMA) (p53 upregulated modulator of apoptosis) (Nakano and Vousden 2001). The transcription of BBC3 is also stimulated by p53 family members TP63 (p63) and TP73 (p73) (Bergamaschi et al. 2004, Patel et al. 2008). ASPP proteins PPP1R13B (ASPP1) and TP53BP2 (ASPP2) form a complex with p53 family members and enhance transcriptional activation of BBC3 (Bergamaschi et al. 2004, Patel et al. 2008, Wilson et al. 2013).
			R-HSA-140214 (Reactome)	TP53 (p53) stimulates transcription of PMAIP1 (NOXA) (Oda et al. 2000, Li et al. 2004). The complex of TP53 with ASPP proteins PPP1R13B (ASPP1) or TP53BP2 (ASPP2) is likely involved in the transcriptional activation of PMAIP1 (Wang et al. 2012, Wilson et al. 2013).
			R-HSA-3700981 (Reactome)	TP53 (p53) binds the p53 response element in the promoter of the BAX gene (Miyashita and Reed 1995). TP53 family members TP63 (p63) and TP73 (p73) can also bind the BAX promoter. Complex formation between ASPP proteins PPP1R13B (ASPP1) or TP53BP2 (ASPP2) and p53 family members TP53 (Samuels-Lev et al. 2001), TP63 or TP73 (Bergamaschi et al. 2004) enhances binding of p53 family members to the BAX promoter.
			R-HSA-3700984 (Reactome)	BAX is a member of the group of pro-apoptotic proteins possessing the BH3 domain. These proteins undergo conformational activation leading to oligomerization and insertion in the outer mitochondrial membrane. This process is presumed to result in permeabilization of outer mitochondrial membrane and egress of apoptogenic factors, such as cytochrome C, that activate the caspase cascade leading to cellular demise. BAX gene transcription is stimulated by binding of TP53 (p53) (Miyashita and Reed 1995) or p53 family members TP63 (p63) and TP73 (p73) (Bergamaschi et al. 2004) to the p53 response element in the BAX gene promoter. ASSP proteins PPP1R13B (ASPP1) and TP53BP2 (ASPP2) form a complex with p53 family members and enhance transcription of the BAX gene (Samuels-Lev et al. 2001, Bergamaschi et al. 2004).
			R-HSA-4331331 (Reactome)	TP53 (p53) binds the promoter of the PMAIP1 (NOXA) gene to induce PMAIP1 transcription (Oda et al. 2000, Li et al. 2004). TP53 likely associates with the PMAIP1 promoter as part of the complex with ASPP proteins PPP1R13B (ASPP1) or TP53BP2 (ASPP2) (Wang et al. 2012, Wilson et al. 2013).
			R-HSA-4331340 (Reactome)	TP53 (p53) binding sites are found in the promoter (Han et al. 2001) and intron 1 (Nakano and Vousden 2001) of the BBC3 (PUMA) gene, and are necessary for TP53-mediated induction of BBC3 transcription. TP53 family members TP63 (p63) and TP73 (p73) can also bind p53 response elements within the BBC3 gene locus (Bergamaschi et al. 2004, Patel et al. 2008). Formation of the complex between TP53 family members and ASPP proteins PPP1R13B (ASPP1) or TP53BP2 (ASPP2) enhances binding of the p53 family members to the BBC3 gene locus (Bergamaschi et al. 2004, Patel et al. 2008, Wilson et al. 2013).
			R-HSA-5633295 (Reactome)	TP53 (p53) binds p53-response element(s) in the promoter of the NDRG1 gene (Stein et al. 2004, Zhang et al. 2007).
			R-HSA-5633314 (Reactome)	Binding of TP53 (p53) to the NDRG1 gene promoter stimulates NDRG1 expression (Stein et al. 2004, Zhang et al. 2007). NDRG1 may positively regulate TP53-mediated apoptosis (Stein et al. 2004) or TP53-mediated cell cycle arrest (Zhang et al. 2007). The exact function of NDRG1 has not been elucidated. Most studies suggest that NDRG1 has a tumor suppressive role, but there are conflicting reports, showing that NDRG1 may act as an oncogene in some settings (reviewed by Liu et al. 2012, Sun and Cao 2013).
			R-HSA-5633414 (Reactome)	TP53 (p53) binds p53-binding sites located in the first introns of the TNFRSF10A (DR4) (Liu et al. 2004), TNFRSF10B (DR5) (Takimoto et al. 2000), TNFRSF10C (DCR1) (Ruiz de Almodovar et al. 2004) and TNFRSF10D (DCR2) (Liu et al. 2005) genes.
			R-HSA-5633441 (Reactome)	TP53 (p53) directly stimulates transcription of genes encoding TRAIL (TNF-related apoptosis-inducing ligand) receptors, also known as death receptors, TNFRSF10A (DR4) (Guan et al. 2001, Liu et al. 2004), TNFRSF10B (DR5) (Wu et al. 1997, Takimoto et al. 2000), TNFRSF10C (DCR1) (Ruiz de Almodovar et al. 2004) and TNFRSF10D (DCR2) (Liu et al. 2005). These receptors are involved in TRAIL signaling, which constitutes a part of the extrinsic apoptotis pathway.
			R-HSA-6791285 (Reactome)	TP53 (p53) binds evolutionarily conserved p53 response elements in the promoter of the BID gene (Sax et al. 2002).
			R-HSA-6791291 (Reactome)	TP53 (p53) directly stimulates BID gene transcription by binding to p53 response elements in the BID gene promoter (Sax et al. 2002).
			R-HSA-6791302 (Reactome)	TP53 (p53) binds the promoter of the AIFM2 (AMID) gene, which contains two p53 response elements (Wu et al. 2004).
			R-HSA-6791306 (Reactome)	TP53 (p53) directly stimulates transcription of the AIFM2 (AMID) gene upon binding to p53 response elements in the promoter of the AIFM2 gene. AIFM2 encodes a mitochondrial outer membrane protein implicated in caspase-independent apoptosis (Wu et al. 2004).
			R-HSA-6791323 (Reactome)	Binding of TP53 (p53) to p53 response element(s) in the first intron and, possibly, the promoter region of BCL2L14 stimulates transcription of the BCL2L14 gene. BCL2L14 (BCLG) is a BCL2 family member with an unknown function and a proposed but uncertain pro-apoptotic role (Guo et al. 2001, Giam et al. 2012).
			R-HSA-6791327 (Reactome)	TP53 (p53) binds the p53 response element in the first intron of the BCL2L14 (BCLG) gene. Another p53 response element is found in the promoter region of the BCL2L14 gene but seems to interact with TP53 with low affinity (Miled et al. 2005).
			R-HSA-6791348 (Reactome)	Once bound to the p53 response element in the promoter of the APAF1 gene, TP53 (p53) stimulates APAF1 transcription (Robles et al. 2001). APAF1 participates in the intrinsic apoptosis pathway, where its interaction with cytochrome C mediates the autocatalytic activation of pro-caspase-9 (Hu et al. 1999).
			R-HSA-6791349 (Reactome)	TP53 (p53) binds the p53 response element in the promoter of the APAF1 gene (Robles et al. 2001).
			R-HSA-6797763 (Reactome)	Upon binding to the p53 response element in the promoter of the BIRC5 (survivin) gene, TP53 (p53) inhibits transcription of BIRC5, an inhibitor of apoptosis (Hoffman et al. 2002).
			R-HSA-6797766 (Reactome)	TP53 (p53) binds the p53 response element in the promoter of the BIRC5 (survivin) gene (Hoffman et al. 2002).
			R-HSA-6797993 (Reactome)	In hypoxic cells, TP53 (p53) binds p53 responsive elements in the BNIP3L gene. CREBBP (CBP) also localizes to the BNIP3L gene under hypoxic conditions, in vicinity to some of the p53 response elements, which is probably regulated by HIF1A (Fei et al. 2004).
			R-HSA-6798004 (Reactome)	TP53 (p53) and CREBBP (CBP) bound to the BNIP3L gene stimulate expression of the BNIP3L. BNIP3L is an outer mitochondrial membrane protein that belongs to the BCL2 family and promotes apoptosis of cells under hypoxic stress (Fei et al. 2004).
			R-HSA-6798081 (Reactome)	Upon binding to the p53 response element in the promoter of the caspase-1 (CASP1) gene, TP53 (p53), TP63 (p63) or TP73 (p73) stimulates transcription of CASP1 (Gupta et al. 2001, Jain et al. 2005, Celardo et al. 2013). CASP1 acts as the interleukin-1 beta (IL1B) converting enzyme (Cerretti et al. 1992) and is involved in the inflammation-related cell death - pyroptosis (Miura et al. 1993, Brough and Rothwell 2007).
			R-HSA-6798082 (Reactome)	TP53 (p53) (Gupta et al. 2001), TP63 (p63) (Celardo et al. 2013) or TP73 (p73) (Jain et al. 2005) bind the p53 response element in the promoter of the CASP1 (caspase-1) gene.
			R-HSA-6798126 (Reactome)	Binding of TP53 (p53) to the third intron of the CASP6 (caspase-6) gene stimulates CASP6 expression (MacLachlan and El-Deiry 2002).
			R-HSA-6798129 (Reactome)	TP53 (p53) binds the p53 response element located in the third intron of the caspase-6 (CASP6) gene (MacLachlan and El-Deiry 2002).
			R-HSA-6798138 (Reactome)	The CASP10 (caspase-10) gene locus contains multiple p53 response elements that bind TP53 (p53) (Rikhof et al. 2003).
			R-HSA-6798139 (Reactome)	Upon binding to p53 response elements at the CASP10 (caspase-10) gene locus, TP53 (p53) stimulates CASP10 expression (Rikhof et al. 2003). CASP10 is involved in apoptosis triggered by death receptor signaling (Wang et al. 2001, Sprick et al. 2002).
			R-HSA-6798611 (Reactome)	TP53 (p53) bound to the p53 response element in the first intron of the TP53AIP1 (p53AIP1) gene stimulates transcription of TP53AIP1. TP53AIP1 protein product localizes to mitochondria and induces apoptosis through dissipation of the mitochondrial membrane potential via an unknown mechanism (Oda et al. 2000). In order to induce TP53AIP1 transcription, TP53 has to be phosphorylated at serine residue S46. DYRK2 kinase is activated by ATM in response to DNA damage and can phosphorylate TP53 at S46 upstream of TP53AIP1 induction (Taira et al. 2007). The transcription factor ZNF420 (Apak) has a binding site in the first intron of TP53AIP1 that overlaps with the p53 response element. The binding of ZNF420 interferes with the binding of TP53 and results in the repression of TP53AIP1 transcription (Yuan et al. 2012).
			R-HSA-6798615 (Reactome)	TP53 (p53) phosphorylated at serine residue S46 binds the p53 response element in the first intron of the TP53AIP1 (p53AIP1) gene (Oda et al. 2000).
			R-HSA-6798624 (Reactome)	The transcription factor ZNF420 (Apak) has a binding site in the first intron of the TP53AIP1 gene that overlaps with the p53 response element. The binding of ZNF420 interferes with the binding of TP53 and results in the repression of TP53AIP1 transcription (Yuan et al. 2012).
			R-HSA-6799097 (Reactome)	Activated ATM phosphorylates ZNF420 (Apak) at serine residue S68. Phosphorylation at S68 inhibits ZNF420 binding to the first intron of TP53AIP1 (p53AIP1) gene, thus facilitating TP53 (p53)-mediated expression of TP53AIP1 (Yuan et al. 2012). ATM-mediated phosphorylation of ZNF420 also inhibits ZNF420 interaction with TP53 and the consequent TP53 deacetylation (Tian et al. 2009).
			R-HSA-6799416 (Reactome)	The binding of TP53 (p53) to the p53 response element in the second intron of the TP53INP1 (p53DINP1) gene positively regulates TP53INP1 transcription (Okamura et al. 2001).
			R-HSA-6799418 (Reactome)	TP53 (p53) binds the p53 response element located in the second intron of the TP53INP1 (p53DINP1) gene (Okamura et al. 2001).
			R-HSA-6799441 (Reactome)	TP53 (p53) activates transcription of the TP53I3 (PIG3) gene by binding to the pentanucleotide microsatellite sequence in the TP53I3 gene promoter that shares a limited similarity with the consensus p53 response element (Contente et al. 2002). Transcription of the TP53I3 gene can also be activated by p53 family members TP63 (p63) and TP73 (p73) (Bergamaschi et al. 2004). ASPP proteins PPP1R13B (ASPP1) and TP53BP2 (ASPP2) form a complex with p53 family members, leading to increased binding of p53 family members to the TP53I3 promoter and enhanced transcription of TP53I3 (Samuels-Lev et al. 2001, Bergamaschi et al. 2004).
			R-HSA-6799462 (Reactome)	TP53 (p53) binds a pentanucleotide microsatellite sequence in the promoter of the TP53I3 (PIG3) gene that shares a limited similarity with the consensus sequence of the p53 response element (Contente et al. 2002). TP63 (p63) and TP73 (p73), members of the p53 protein family, can also bind the promoter of TP53I3 (Bergamaschi et al. 2004). Formation of a complex between p53 family members and ASSP proteins PPP1R13B (ASPP1) or TP53BP2 (ASPP2) enhances binding of TP53 (Samuels-Lev et al. 2001), TP63 or TP73 to the TP53I3 promoter (Bergamaschi et al. 2004).
			R-HSA-6799466 (Reactome)	TP53I3 (PIG3) forms a homodimer. The dimer interface is formed by two beta strands and an alpha helix of the cofactor-binding domain. Beta strands of the two monomeric subunits are bonded through anti-parallel hydrogen bonds (Porte et al. 2009).
			R-HSA-6799722 (Reactome)	TP53I3 (PIG3) possesses a NADPH quinone reductase activity, with 1,2-naphthoquinone being its preferred substrate. TP53I3 reduces 1,2-naphthoquinone to a highly unstable semiquinone free radical. Semiquinone reacts with oxygen yielding a quinone and superoxide aninon. Reactive oxygen species (ROS) produced as a result of TP53I3 activity contribute to apoptosis (Porte et al. 2009).
			R-HSA-6799733 (Reactome)	Semiquinone spontaneously reacts with oxygen to revert to a quinone state and produces superoxide anion (Oppermann 2007, Porte et al. 2009).
			R-HSA-6799815 (Reactome)	The FAS gene possesses three p53 response elements in the promoter and one p53 response element in its first intron. TP53 family members TP53 (p53), TP63 (p63) and TP73 (p73) can all bind the intronic p53 response element and activate FAS gene transcription. The promoter p53 response elements also contribute to the transcriptional activation of FAS (Schilling et al. 2009). The complex of TP53 (or, probably, TP63 or TP73) with ASSP proteins PPP1R13B (ASPP1) or TP53BP2 (ASPP2) enhances FAS transcription (Wilson et al. 2013). FAS interacts with its natural ligand, CD95L, a member of the TNF cytokine family, to initiate the death signal cascade, which results in programmed cell death. FAS can function as a guardian against autoimmunity and tumor development (Schilling et al. 2009).
			R-HSA-6800001 (Reactome)	The p53 family members TP53 (p53), TP63 (p63), or TP73 (p73), most likely in complex with ASPP proteins PPP1R13B (ASPP1) or TP53BP2 (ASPP2) (Wilson et al. 2013), bind p53 response elements in the first intron and/or promoter of the FAS gene, promoting FAS transcription (Schilling et al. 2009).
			R-HSA-6800035 (Reactome)	IGFBP3 binds a cell death receptor TMEM219 (IGFBP-3R), a single-span transmembrane protein. Activated TMEM219 can trigger apoptosis, probably by directly binding to and activating caspase-8 (CASP8) (Ingermann et al. 2010).
			R-HSA-6800042 (Reactome)	TP53 (p53) binds p53 response elements in the first and second introns of the IGFBP3 gene and promotes its upregulation (Buckbinder et al. 1995). In response to DNA damage and hypoxia, IGFBP3 can also be upregulated in a p53-independent manner (Grimberg et al. 2005).
			R-HSA-6800044 (Reactome)	Binding of TP53 (p53) to p53 response elements in the first and second introns of the IGFBP3 gene upregulates IGFBP3 transcription (Buckbinder et al. 1995). IGFBP3 is one of a family of six homologous proteins that bind IGF1 and IGF2 with high affinity. IGFBP3 contributes to cellular apoptosis in both IGF-dependent and IGF-independent manner (Marzec et al. 2015).
			R-HSA-6800250 (Reactome)	Binding of TP53 (p53) to the p53 response element in the first intron of the BCL6 gene promotes BCL6 transcription (Margalit et al. 2006). BCL6 is a transcriptional repressor that has been implicated as a facilitator of apoptosis, through inhibition of BCL2 expression (Saito et al. 2009), but also as an inhibitor of apoptosis, through inhibition of TP53 expression (Phan and Dalla-Favera 2004).
			R-HSA-6800253 (Reactome)	TP53 (p53) binds the p53 response element located in the first intron of the BCL6 gene. This region of the BCL6 gene is frequently subject to translocations, point mutations and deletions in B-cell non-Hodgkin lymphoma (Margalit et al. 2006).
			R-HSA-6800279 (Reactome)	TP53 (p53) binds an evolutionarily conserved p53 response element in the 5' UTR of the PIDD1 gene (Lin et al. 2000).
			R-HSA-6800396 (Reactome)	Upon binding to the p53 response element in the 5' UTR of the PIDD1 gene, TP53 (p53) promotes PIDD1 transcription (Lin et al. 2000).
			R-HSA-6800490 (Reactome)	In response to DNA damage, activated ATM phosphorylates PIDD1 at threonine residue T788, a prerequisite for the subsequent interaction with CRADD (RAIDD) (Ando et al. 2012).
			R-HSA-6800793 (Reactome)	PIDD1 can localize both to the nucleus and to the cytoplasm. It is not known whether ATM-mediated phosphorylation regulates PIDD1 localization, but PIDDosome formation and caspase-2 activation is thought to be predominantly cytoplasmic (Ando et al. 2012).
			R-HSA-6800794 (Reactome)	PIDD1 phosphorylated by ATM at threonine residue T788 associates with CRADD (RAIDD), forming a multisubunit structure known as the PIDDosome (Tinel and Tschopp 2004, Ando et al. 2012). The PIDDosome consists of 5 molecules of PIDD1 and 5-7 molecules of CRADD (Nematollahi et al. 2015).
			R-HSA-6800797 (Reactome)	The PIDDosome promotes activation of CASP2 (caspase-2) by proteolytic cleavage, triggering apoptosis (Tinel and Tschopp 2004). The PIDDosome may also participate in the proteolytic activation of CASP3 and CASP7 (Berube et al. 2005).
			R-HSA-6800798 (Reactome)	PIDD1, when phosphorylated by ATM at threonine residue T788, associates with CRADD (RAIDD), forming a multisubunit structure known as the PIDDosome (Tinel and Tschopp 2004, Ando et al. 2012). The PIDDosome binds procaspase-2 (CASP2), with CASP2 directly interacting with the CRADD subunit (Tinel and Tschopp 2004).
			R-HSA-6800816 (Reactome)	Binding of TP53 (p53) or TP63 (p63) to p53 response elements in the promoter and/or the first intron of the PERP gene promotes PERP transcription (Attardi et al. 2000, Ihrie et al. 2005). E2F1 may cooperate with TP53 in the transcriptional activation of PERP (Attardi et al. 2000). PERP is a transmembrane protein that specifically localizes to desmosomes and is important for epithelial integrity. PERP is involved in p53-dependent apoptosis (Attardi et al. 2000, Ihrie et al. 2003) and may act through contributing to caspase activation (Davies et al. 2009).
			R-HSA-6800836 (Reactome)	The PERP gene possesses two p53 response elements in its promoter region and at least one p53 response element in its first intron, which are involved in the recruitment of TP53 (p53) or TP63 (p63) to the PERP gene locus (Attardi et al. 2000, Ihrie et al. 2005).
			R-HSA-6801087 (Reactome)	The RABGGTA gene possesses three p53 response elements, one in the promoter and two downstream of the transcription start site. TP53 (p53) can bind, at least, to the promoter p53 response element of the RABGGTA gene (Jen and Cheung 2005).
			R-HSA-6801089 (Reactome)	Binding of TP53 (p53) to the p53 response element in the promoter of the RABGGTA gene promotes RABGGTA transcription (Jen and Cheung 2005).
			R-HSA-6801101 (Reactome)	RABGGTA associates with RABGGTB to form RAB geranylgeranyl transferase (RGGT or RAB GGTase). This was initially shown using proteins purified from rat brain (Seabra et al. 1992), but the complex is evolutionarily conserved in human cells (Baron and Seabra 2008).
			R-HSA-6801109 (Reactome)	RAB escort protein CHM (REP1) binds the RAB geranylgeranyl transferase complex, RGGT, composed of RABGGTA and RABGGTB (Baron and Seabra 2008). The interaction between CHM and the RGGT complex is enhanced by the presence of phosphoisoprenoids (Thoma et al. 2001). The complex of RGGT and CHM catalyzes geranylgeranylation of small GTPases RAB1A, RAB3A and RAB5A, which is needed for the membrane localization of RABs (Farnsworth et al. 1994). RAB geranylgeranyl transferase can play an anti-apoptotic role, through an unknown mechanism (Lackner et al. 2005). RAB5A, the substrate of RGGT:CHM complex, was shown to positively regulate formation of autophagosomes (Li et al. 2013).
			R-HSA-6801166 (Reactome)	TP53 (p53) binds the p53 response element in the promoter of the STEAP3 (TSAP6) gene (Passer et al. 2003).
			R-HSA-6801184 (Reactome)	Binding of TP53 (p53) to the p53 response element in the promoter of the STEAP3 (TSAP6) gene promotes STEAP3 transcription (Passer et al. 2003). Tumor suppressor-activated pathway 6 (TSAP6) was initially discovered as differentially regulated following p53 activation and was later shown to be strongly activated in tumor suppression and reversion, and was hence named TSAP6. TSAP6 knockdown results in inhibition of apoptosis. TSAP6 binds to and cooperates with BNIP3L (NIX), a pro-apoptotic BH3-only BCL2-family member, and MYT1 kinase, a negative regulator of the G2/M transition (Lespagnol et al. 2008).
			R-HSA-6801195 (Reactome)	STEAP3 (TSAP6) forms a complex with a pro-apoptotic protein BNIP3L (NIX) and cooperates with BNIP3L in promoting apoptosis, but the exact mechanism is not known (Passer et al. 2003). While STEAP3 localizes to endosome membranes, BNIP3L localizes to the outer mitochondrial membrane. BNIP3L has recently been implicated in the relocalization of endo-lysosomes to inner mitochondrial compartments, which can play a role in endo-lysosomal processing of mitochondria (Hamacher-Brady et al. 2014).
			R-HSA-6801209 (Reactome)	TP53 (p53) binds the p53 response element in the second exon of the TRIAP1 (p53CSV) gene (Park and Nakamura 2005).
			R-HSA-6801213 (Reactome)	Binding of TP53 (p53) to the p53 response element in the second intron of the TRIAP1 (TP53-regulated inhibitor of apoptosis, also known as p53 survival factor or p53CSV) gene induces TRIAP1 transcription (Park and Nakamura 2005). Recently, TRIAP1 has been characterized as a gene-specific repressor of p21 (CDKN1A). TRIAP1 knockdown leads to augmented p21 expression before and during p53 activation and thus slows down cell proliferation (Andrysik et al. 2013).
			R-HSA-6801242 (Reactome)	In the mitochondrial intermembrane space, TP53-regulated inhibitor of apoptosis 1 (TRIAP1) forms a complex with mitochondrial PRELI domain-containing protein 1 (PRELID1, PRELI) (Potting et al. 2013). TRIAP1 is also proposed to form a complex with PRELI domain containing protein 3A (PRELID3A) (Miliara et al. 2015).
			R-HSA-6801250 (Reactome)	The complex of TP53-regulated inhibitor of apoptosis 1 (TRIAP1) and mitochondrial PRELI domain-containing protein 1 PRELID1 (TRIAP1:PRELID1) facilitates transport of phosphatidic acid (PA) from the outer mitochondrial membrane to the inner mitochondrial membrane. At the inner mitochondrial membrane, the PA is used for the synthesis of cardiolipin (CL). CL prevents the release of cytochrome C from mitochondria, thus playing an anti-apoptotic role (Potting et al. 2013). The complex between TRIAP1 and PRELI domain containing protein 3A (PRELID3A) is suggested to perform the same PA transport activity (Miliara et al. 2015)
			R-HSA-6801355 (Reactome)	TP53 (p53) binds the p53 response element in the promoter of the NLRC4 (Ipaf) gene (Sadasivam et al. 2005).
			R-HSA-6801415 (Reactome)	The binding of TP53 (p53) to the p53 response element in the promoter of the NLRC4 (Ipaf) gene promotes NLRC4 transcription. NLRC4 is an activator of caspase-1 (CASP1) (Poyet et al. 2001), which is also a TP53 target. NLRC4 and CASP1 play an important role in innate immunity via inflammasome-mediated destruction of pathogenic bacteria and fungi (Schroder and Tschopp 2010). NLRC4 contributes to cell death (Sadasivam et al. 2005), possibly through interleukin-1-mediated pyroptosis (Brough and Rothwell 2007).
RABGGTA Gene			R-HSA-6801087 (Reactome)
RABGGTA Gene			R-HSA-6801089 (Reactome)
	RABGGTA	Arrow	R-HSA-6801089 (Reactome)
RABGGTA			R-HSA-6801101 (Reactome)
RABGGTB			R-HSA-6801101 (Reactome)
	RGGT:CHM	Arrow	R-HSA-6801109 (Reactome)
	RGGT	Arrow	R-HSA-6801101 (Reactome)
RGGT			R-HSA-6801109 (Reactome)
STEAP3 Gene			R-HSA-6801166 (Reactome)
STEAP3 Gene			R-HSA-6801184 (Reactome)
	STEAP3:BNIP3L	Arrow	R-HSA-6801195 (Reactome)
	STEAP3	Arrow	R-HSA-6801184 (Reactome)
STEAP3			R-HSA-6801195 (Reactome)
TMEM219			R-HSA-6800035 (Reactome)
	TNFRSF10A, TNFRSF10B, TNFRSF10C, TNFRSF10D	Arrow	R-HSA-5633441 (Reactome)
TNFRSF10A,TNFRSF10B,TNFRSF10C,TNFRSF10D Genes			R-HSA-5633414 (Reactome)
TNFRSF10A,TNFRSF10B,TNFRSF10C,TNFRSF10D Genes			R-HSA-5633441 (Reactome)
TP53AIP1 Gene			R-HSA-6798611 (Reactome)
TP53AIP1 Gene			R-HSA-6798615 (Reactome)
TP53AIP1 Gene			R-HSA-6798624 (Reactome)
	TP53AIP1	Arrow	R-HSA-6798611 (Reactome)
	TP53I3 Dimer	Arrow	R-HSA-6799466 (Reactome)
TP53I3 Dimer		mim-catalysis	R-HSA-6799722 (Reactome)
TP53I3 Gene			R-HSA-6799441 (Reactome)
TP53I3 Gene			R-HSA-6799462 (Reactome)
	TP53I3	Arrow	R-HSA-6799441 (Reactome)
TP53I3			R-HSA-6799466 (Reactome)
TP53INP1 Gene			R-HSA-6799416 (Reactome)
TP53INP1 Gene			R-HSA-6799418 (Reactome)
	TP53INP1	Arrow	R-HSA-6799416 (Reactome)
TRIAP1 Gene			R-HSA-6801209 (Reactome)
TRIAP1 Gene			R-HSA-6801213 (Reactome)
	TRIAP1:PRELID1, PRELID3A	Arrow	R-HSA-6801242 (Reactome)
TRIAP1:PRELID1, PRELID3A		mim-catalysis	R-HSA-6801250 (Reactome)
	TRIAP1	Arrow	R-HSA-6801213 (Reactome)
TRIAP1			R-HSA-6801242 (Reactome)
	ZNF420:TP53AIP1 Gene	Arrow	R-HSA-6798624 (Reactome)
ZNF420:TP53AIP1 Gene		TBar	R-HSA-6798611 (Reactome)
ZNF420			R-HSA-6798624 (Reactome)
ZNF420			R-HSA-6799097 (Reactome)
p-S15,S20,S46-TP53 Tetramer:TP53AIP1 Gene		Arrow	R-HSA-6798611 (Reactome)
	p-S15,S20,S46-TP53 Tetramer:TP53AIP1 Gene	Arrow	R-HSA-6798615 (Reactome)
p-S15,S20,S46-TP53 Tetramer			R-HSA-6798615 (Reactome)
	p-S15,S20-TP53 Tetramer:AIFM2 Gene	Arrow	R-HSA-6791302 (Reactome)
p-S15,S20-TP53 Tetramer:AIFM2 Gene		Arrow	R-HSA-6791306 (Reactome)
p-S15,S20-TP53 Tetramer:APAF1 Gene		Arrow	R-HSA-6791348 (Reactome)
	p-S15,S20-TP53 Tetramer:APAF1 Gene	Arrow	R-HSA-6791349 (Reactome)
p-S15,S20-TP53 Tetramer:BCL2L14 Gene		Arrow	R-HSA-6791323 (Reactome)
	p-S15,S20-TP53 Tetramer:BCL2L14 Gene	Arrow	R-HSA-6791327 (Reactome)
p-S15,S20-TP53 Tetramer:BCL6 Gene		Arrow	R-HSA-6800250 (Reactome)
	p-S15,S20-TP53 Tetramer:BCL6 Gene	Arrow	R-HSA-6800253 (Reactome)
	p-S15,S20-TP53 Tetramer:BID Gene	Arrow	R-HSA-6791285 (Reactome)
p-S15,S20-TP53 Tetramer:BID Gene		Arrow	R-HSA-6791291 (Reactome)
	p-S15,S20-TP53 Tetramer:BIRC5 Gene	Arrow	R-HSA-6797766 (Reactome)
p-S15,S20-TP53 Tetramer:BIRC5 Gene		TBar	R-HSA-6797763 (Reactome)
	p-S15,S20-TP53 Tetramer:CASP10 Gene	Arrow	R-HSA-6798138 (Reactome)
p-S15,S20-TP53 Tetramer:CASP10 Gene		Arrow	R-HSA-6798139 (Reactome)
p-S15,S20-TP53 Tetramer:CASP6 Gene		Arrow	R-HSA-6798126 (Reactome)
	p-S15,S20-TP53 Tetramer:CASP6 Gene	Arrow	R-HSA-6798129 (Reactome)
	p-S15,S20-TP53 Tetramer:CREBBP:BNIP3L Gene	Arrow	R-HSA-6797993 (Reactome)
p-S15,S20-TP53 Tetramer:CREBBP:BNIP3L Gene		Arrow	R-HSA-6798004 (Reactome)
	p-S15,S20-TP53 Tetramer:IGFBP3 Gene	Arrow	R-HSA-6800042 (Reactome)
p-S15,S20-TP53 Tetramer:IGFBP3 Gene		Arrow	R-HSA-6800044 (Reactome)
	p-S15,S20-TP53 Tetramer:NDRG1 Gene	Arrow	R-HSA-5633295 (Reactome)
p-S15,S20-TP53 Tetramer:NDRG1 Gene		Arrow	R-HSA-5633314 (Reactome)
	p-S15,S20-TP53 Tetramer:PIDD1 Gene	Arrow	R-HSA-6800279 (Reactome)
p-S15,S20-TP53 Tetramer:PIDD1 Gene		Arrow	R-HSA-6800396 (Reactome)
p-S15,S20-TP53 Tetramer:PMAIP1 Gene		Arrow	R-HSA-140214 (Reactome)
	p-S15,S20-TP53 Tetramer:PMAIP1 Gene	Arrow	R-HSA-4331331 (Reactome)
	p-S15,S20-TP53 Tetramer:RABGGTA Gene	Arrow	R-HSA-6801087 (Reactome)
p-S15,S20-TP53 Tetramer:RABGGTA Gene		Arrow	R-HSA-6801089 (Reactome)
	p-S15,S20-TP53 Tetramer:STEAP3 Gene	Arrow	R-HSA-6801166 (Reactome)
p-S15,S20-TP53 Tetramer:STEAP3 Gene		Arrow	R-HSA-6801184 (Reactome)
	p-S15,S20-TP53 Tetramer:TNFRSF10A,TNFRSF10B,TNFRSF10C,TNFRSF10D Genes	Arrow	R-HSA-5633414 (Reactome)
p-S15,S20-TP53 Tetramer:TNFRSF10A,TNFRSF10B,TNFRSF10C,TNFRSF10D Genes		Arrow	R-HSA-5633441 (Reactome)
p-S15,S20-TP53 Tetramer:TP53INP1 Gene		Arrow	R-HSA-6799416 (Reactome)
	p-S15,S20-TP53 Tetramer:TP53INP1 Gene	Arrow	R-HSA-6799418 (Reactome)
	p-S15,S20-TP53 Tetramer:TRIAP1 Gene	Arrow	R-HSA-6801209 (Reactome)
p-S15,S20-TP53 Tetramer:TRIAP1 Gene		Arrow	R-HSA-6801213 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-4331331 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-5633295 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-5633414 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6791285 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6791302 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6791327 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6791349 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6797766 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6797993 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6798129 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6798138 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6799418 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6800042 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6800253 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6800279 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6801087 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6801166 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6801209 (Reactome)
p-S15,S20-TP53 Tetramer			R-HSA-6801355 (Reactome)
p-S15,S20-TP53,TP63,TP73			R-HSA-6798082 (Reactome)
p-S15,S20-TP53,TP63			R-HSA-6800836 (Reactome)
	p-S15,S20-TP53:NLRC4 Gene	Arrow	R-HSA-6801355 (Reactome)
p-S15,S20-TP53:NLRC4 Gene		Arrow	R-HSA-6801415 (Reactome)
p-S1981,Ac-K3016-ATM		mim-catalysis	R-HSA-6799097 (Reactome)
p-S1981,Ac-K3016-ATM		mim-catalysis	R-HSA-6800490 (Reactome)
	p-S68-ZNF420	Arrow	R-HSA-6799097 (Reactome)
	p-T788-PIDD1	Arrow	R-HSA-6800490 (Reactome)
	p-T788-PIDD1	Arrow	R-HSA-6800793 (Reactome)
p-T788-PIDD1			R-HSA-6800793 (Reactome)
p-T788-PIDD1			R-HSA-6800794 (Reactome)
	semiquinone	Arrow	R-HSA-6799722 (Reactome)
semiquinone			R-HSA-6799733 (Reactome)