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DROME:Q9N6D8

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Species (Taxon ID) Drosophila melanogaster (Fruit fly). (7227)
Gene Name(s) No Information Provided. (synonyms: prac (ECO:0000313 with EMBL:AAL56639.1))
Protein Name(s) GH11591p (ECO:0000313 with EMBL:AAL39241.1)

P53 tumor suppressor-like protein (ECO:0000313 with EMBL:AAF61572.1) P53-like regulator of apoptosis and cell cycle (ECO:0000313 with EMBL:AAL56639.1) Transcription factor (ECO:0000313 with EMBL:AAF74277.1) Transcription factor p53 (ECO:0000313 with EMBL:AAF75270.1) p53, isoform A (ECO:0000313 with EMBL:AAF56087.2) p53, isoform C (ECO:0000313 with EMBL:ACZ94989.1)

External Links
UniProt Q9N6D8
EMBL AF224713
AF224714
AE014297
AF244918
AF250918
AF263722
AY069096
AF192555
AE014297
RefSeq NP_001163694.1
NP_996268.1
UniGene Dm.3257
SMR Q9N6D8
IntAct Q9N6D8
MINT MINT-1014674
STRING 7227.FBpp0083753
EnsemblMetazoa FBtr0084359
FBtr0301765
GeneID 2768677
KEGG dme:Dmel_CG33336
UCSC CG33336-RA
CTD 2768677
FlyBase FBgn0039044
KO K10149
GenomeRNAi 2768677
NextBio 848043
Proteomes UP000000803
GO GO:0000785
GO:0005829
GO:0005634
GO:0005667
GO:0003682
GO:0001047
GO:0003684
GO:0003690
GO:0002039
GO:0043565
GO:0003700
GO:0008134
GO:0031624
GO:0031625
GO:0006919
GO:0006915
GO:0008219
GO:0006974
GO:0071480
GO:0009267
GO:0034644
GO:0008340
GO:0030330
GO:0006978
GO:0035234
GO:0008630
GO:0042771
GO:0031571
GO:0043553
GO:0046533
GO:0042992
GO:0000122
GO:0014016
GO:0007405
GO:0048477
GO:0045787
GO:2000685
GO:0040010
GO:0043568
GO:0016239
GO:0040018
GO:0045944
GO:0045893
GO:0007131
GO:0042127
GO:0006282
GO:0043523
GO:0046620
GO:0006357
GO:1990248
GO:0010332
GO:0010212
GO:0009314
GO:0009411
GO:0010165
GO:0042246
Gene3D 2.60.40.720
InterPro IPR008967
IPR012346
IPR024631
IPR011615
IPR002117
PANTHER PTHR11447
Pfam PF00870
PF11619
SUPFAM SSF49417

Annotations

Qualifier GO ID GO term name Reference ECO ID ECO term name with/from Aspect Extension Notes Status
GO:0008340

determination of adult lifespan

17686972

ECO:0000315

P

Fig 1A demonstrated that pan-neuronal expression of dominant negative Dmp53(DN-Dmp53) extends average lifespan up to 19% comparing to the control flies. Fig 1C and 1D shows that DN-Dmp53 expression in insulin producing cells (IPC) using GAL4 drivers derived from dILP2 promoter region extends lifespan up to 19%.

Missing: reference

GO:0032095

regulation of response to food

17686972

ECO:0000315

P

SI Table 2 demonstrates that on standard cornmeal food, the expression of wild-type Dmp53 in IPC reduce the mean lifespan by 13% (see row: IPC Rulifson driver with wt-Dmp53). However, on low calories food, the expression of DN-Dmp53 in IPC increase lifespan by 3% (see row IPC Shen driver low cal), while on high calories food, the expression of DN-Dmp53 in IPC increases lifespan by 13% (see row IPC Shen driver high cal).

Missing: reference

GO:0046628

positive regulation of insulin receptor signaling pathway

17686972

ECO:0000315

P

SI Fig 6 illustrates that flies expressing DN-Dmp53 weigh less and gain weight slower in the first ten days after eclosion comparing to controls. Therefore, this indicates that wild type Dmp53 positively regulate of IIS pathway. SI Fig 7 shows that mRNA of dILP2 is 60% reduced in flies expressing DN-Dmp53, therefore IIS pathway activation is reduced and wild type Dmp53 acts as positive regulator of IIS.

Missing: reference

GO:0046628

positive regulation of insulin receptor signaling pathway

17686972

ECO:0000314

P

Fig 2A, 2B, 2C, 2D, 2E demonstrate reduction of plasma membrane bound tGPH and increase in cytosolic staining of tGPH, which indicates reduced IIS activity in flies expressing DN-Dmp53 as a result of decreased PI3K activity. Fig 4A & 4B shows increased nuclear dFoxO localization in DN-Dmp53 expressing cells comparing to controls.

Missing: reference

GO:0040010

positive regulation of growth rate

17686972

ECO:0000315

P

SI Fig 6 illustrates that flies expressing DN-Dmp53 weigh less and gain weight slower in the first ten days after eclosion comparing to controls. Therefore, this indicates that wild type Dmp53 positively regulate of IIS pathway.

Missing: reference

GO:0040018

positive regulation of multicellular organism growth

17686972

ECO:0000315

P

SI Fig 6 illustrates that flies expressing DN-Dmp53 weigh less and gain weight slower in the first ten days after eclosion comparing to controls. Therefore, this indicates that wild type Dmp53 positively regulate of IIS pathway.


Missing: reference

GO:0043568

positive regulation of insulin-like growth factor receptor signaling pathway

17686972

ECO:0000315

P

SI Fig 6 illustrates that flies expressing DN-Dmp53 weigh less and gain weight slower in the first ten days after eclosion comparing to controls. Therefore, this indicates that wild type Dmp53 positively regulate of IIS pathway. SI Fig 7 shows that mRNA of dILP2 is 60% reduced in flies expressing DN-Dmp53, therefore IIS pathway activation is reduced and wild type Dmp53 acts as positive regulator of IIS.

Missing: reference

GO:0043568

positive regulation of insulin-like growth factor receptor signaling pathway

17686972

ECO:0000314

P

Fig 2A, 2B, 2C, 2D, 2E demonstrate reduction of plasma membrane bound tGPH and increase in cytosolic staining of tGPH, which indicates reduced IIS activity in flies expressing DN-Dmp53 as a result of decreased PI3K activity. Fig 4A & 4B shows increased nuclear dFoxO localization in DN-Dmp53 expressing cells comparing to cytoplasmic localization in controls.

Missing: reference

GO:0014067

negative regulation of phosphoinositide 3-kinase cascade

17686972

ECO:0000314

P

Fig 2A, 2B, 2C, 2D, 2E demonstrate reduction of plasma membrane bound tGPH and increase in cytosolic staining of tGPH, which indicates reduced IIS activity in flies expressing DN-Dmp53 as a result of decreased PI3K activity.

Missing: reference

GO:0042992

negative regulation of transcription factor import into nucleus

17686972

ECO:0000314

P

Fig 4A & 4B shows increased nuclear dFoxO localization in DN-Dmp53 expressing cells comparing to cytoplasmic localization in controls


Missing: reference

involved_in

GO:0045944

positive regulation of transcription by RNA polymerase II

PMID:17686972[1]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0043568

positive regulation of insulin-like growth factor receptor signaling pathway

PMID:17686972[1]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0043553

negative regulation of phosphatidylinositol 3-kinase activity

PMID:17686972[1]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0042307

positive regulation of protein import into nucleus

PMID:17686972[1]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

has_regulation_target:(UniProtKB:Q95V55)

Seeded From UniProt

complete

involved_in

GO:0040018

positive regulation of multicellular organism growth

PMID:17686972[1]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0040010

positive regulation of growth rate

PMID:17686972[1]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0008340

determination of adult lifespan

PMID:17686972[1]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0010212

response to ionizing radiation

PMID:17933869[2]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0045893

positive regulation of transcription, DNA-templated

PMID:17933869[2]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0006919

activation of cysteine-type endopeptidase activity involved in apoptotic process

PMID:17310982[3]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

enables

GO:0031625

ubiquitin protein ligase binding

PMID:17170702[4]

ECO:0000353

physical interaction evidence used in manual assertion

FB:FBgn0039875

F

Seeded From UniProt

complete

involved_in

GO:0008340

determination of adult lifespan

PMID:16303568[5]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0042771

intrinsic apoptotic signaling pathway in response to DNA damage by p53 class mediator

PMID:16860746[6]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0042246

tissue regeneration

PMID:16920621[7]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0009411

response to UV

PMID:16412438[8]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0045787

positive regulation of cell cycle

PMID:16326395[9]

ECO:0000316

genetic interaction evidence used in manual assertion

FB:FBgn0019624

P

Seeded From UniProt

complete

involved_in

GO:0008340

determination of adult lifespan

PMID:16303568[5]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0006915

apoptotic process

PMID:16079158[10]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0060785

regulation of apoptosis involved in tissue homeostasis

PMID:25882045[11]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

colocalizes_with

GO:0010369

chromocenter

PMID:25882045[11]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

involved_in

GO:0010212

response to ionizing radiation

PMID:25882045[11]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0042771

intrinsic apoptotic signaling pathway in response to DNA damage by p53 class mediator

PMID:25882045[11]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:1990248

regulation of transcription from RNA polymerase II promoter in response to DNA damage

PMID:25882045[11]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

enables

GO:0000976

transcription regulatory region sequence-specific DNA binding

PMID:25453105[12]

ECO:0000314

direct assay evidence used in manual assertion

F

Seeded From UniProt

complete

involved_in

GO:0006974

cellular response to DNA damage stimulus

PMID:14532134[13]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0006282

regulation of DNA repair

PMID:14729967[14]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:2000685

positive regulation of cellular response to X-ray

PMID:14729967[14]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0042771

intrinsic apoptotic signaling pathway in response to DNA damage by p53 class mediator

PMID:12935877[15]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0009314

response to radiation

PMID:12672954[16]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0008219

cell death

PMID:12672954[16]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0006357

regulation of transcription by RNA polymerase II

PMID:25211335[17]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0042594

response to starvation

PMID:25017064[18]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0010212

response to ionizing radiation

PMID:24240233[19]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

enables

GO:0001097

TFIIH-class transcription factor complex binding

PMID:23549790[20]

ECO:0000353

physical interaction evidence used in manual assertion

FB:FBgn0261109

F

Seeded From UniProt

complete

involved_in

GO:0014016

neuroblast differentiation

PMID:22140513[21]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0007405

neuroblast proliferation

PMID:22140513[21]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

enables

GO:0031624

ubiquitin conjugating enzyme binding

PMID:21205821[22]

ECO:0000353

physical interaction evidence used in manual assertion

FB:FBgn0004436

F

Seeded From UniProt

complete

involved_in

GO:0045893

positive regulation of transcription, DNA-templated

PMID:10778860[23]

ECO:0000314

direct assay evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0042771

intrinsic apoptotic signaling pathway in response to DNA damage by p53 class mediator

PMID:10778860[23]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0046620

regulation of organ growth

PMID:21179433[24]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0042127

regulation of cell population proliferation

PMID:21179433[24]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0035234

ectopic germ cell programmed cell death

PMID:20838898[25]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0048477

oogenesis

PMID:20522776[26]

ECO:0000316

genetic interaction evidence used in manual assertion

FB:FBgn0002989

P

Seeded From UniProt

complete

involved_in

GO:0007131

reciprocal meiotic recombination

PMID:20522776[26]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0046533

negative regulation of photoreceptor cell differentiation

PMID:19960025[27]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

part_of

GO:0005634

nucleus

PMID:19153663[28]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

colocalizes_with

GO:0035327

transcriptionally active chromatin

PMID:19153663[28]

ECO:0000314

direct assay evidence used in manual assertion

C

Seeded From UniProt

complete

involved_in

GO:0009267

cellular response to starvation

PMID:18794330[29]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0016239

positive regulation of macroautophagy

PMID:18794330[29]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0008630

intrinsic apoptotic signaling pathway in response to DNA damage

PMID:18688282[30]

ECO:0000315

mutant phenotype evidence used in manual assertion

P

Seeded From UniProt

complete

enables

GO:0008134

transcription factor binding

PMID:18549481[31]

ECO:0000353

physical interaction evidence used in manual assertion

FB:FBgn0026262

F

Seeded From UniProt

complete

enables

GO:0003677

DNA binding

GO_REF:0000002

ECO:0000256

match to sequence model evidence used in automatic assertion

InterPro:IPR002117
InterPro:IPR012346

F

Seeded From UniProt

complete

enables

GO:0003700

DNA-binding transcription factor activity

GO_REF:0000002

ECO:0000256

match to sequence model evidence used in automatic assertion

InterPro:IPR002117
InterPro:IPR008967
InterPro:IPR012346

F

Seeded From UniProt

complete

part_of

GO:0005634

nucleus

GO_REF:0000002

ECO:0000256

match to sequence model evidence used in automatic assertion

InterPro:IPR002117
InterPro:IPR012346

C

Seeded From UniProt

complete

involved_in

GO:0006355

regulation of transcription, DNA-templated

GO_REF:0000002

ECO:0000256

match to sequence model evidence used in automatic assertion

InterPro:IPR002117
InterPro:IPR008967
InterPro:IPR012346

P

Seeded From UniProt

complete

involved_in

GO:0006915

apoptotic process

GO_REF:0000002

ECO:0000256

match to sequence model evidence used in automatic assertion

InterPro:IPR002117

P

Seeded From UniProt

complete

enables

GO:0044212

transcription regulatory region DNA binding

GO_REF:0000002

ECO:0000256

match to sequence model evidence used in automatic assertion

InterPro:IPR011615

F

Seeded From UniProt

complete

involved_in

GO:0009314

response to radiation

PMID:11139272[32]

ECO:0000304

author statement supported by traceable reference used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0006357

regulation of transcription by RNA polymerase II

PMID:11139272[32]

ECO:0000304

author statement supported by traceable reference used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0030330

DNA damage response, signal transduction by p53 class mediator

PMID:12072176[33]
PMID:12006672[34]

ECO:0000304

author statement supported by traceable reference used in manual assertion


P

Seeded From UniProt

complete

involved_in

GO:0006915

apoptotic process

PMID:12072176[33]
PMID:10910336[35]

ECO:0000304

author statement supported by traceable reference used in manual assertion


P

Seeded From UniProt

complete

involved_in

GO:0008630

intrinsic apoptotic signaling pathway in response to DNA damage

PMID:12006672[34]

ECO:0000304

author statement supported by traceable reference used in manual assertion

P

Seeded From UniProt

complete

involved_in

GO:0042771

intrinsic apoptotic signaling pathway in response to DNA damage by p53 class mediator

PMID:11063934[36]

ECO:0000304

author statement supported by traceable reference used in manual assertion

P

Seeded From UniProt

complete

Notes

References

See Help:References for how to manage references in GONUTS.

  1. 1.0 1.1 1.2 1.3 1.4 1.5 1.6 Bauer, JH et al. (2007) Expression of dominant-negative Dmp53 in the adult fly brain inhibits insulin signaling. Proc. Natl. Acad. Sci. U.S.A. 104 13355-60 PubMed GONUTS page
  2. 2.0 2.1 Bodai, L et al. (2007) Daxx-like protein of Drosophila interacts with Dmp53 and affects longevity and Ark mRNA level. J. Biol. Chem. 282 36386-93 PubMed GONUTS page
  3. Akdemir, F et al. (2007) p53 directs focused genomic responses in Drosophila. Oncogene 26 5184-93 PubMed GONUTS page
  4. Yamasaki, S et al. (2007) Cytoplasmic destruction of p53 by the endoplasmic reticulum-resident ubiquitin ligase 'Synoviolin'. EMBO J. 26 113-22 PubMed GONUTS page
  5. 5.0 5.1 Bauer, JH et al. (2005) Neuronal expression of p53 dominant-negative proteins in adult Drosophila melanogaster extends life span. Curr. Biol. 15 2063-8 PubMed GONUTS page
  6. Colombani, J et al. (2006) Dmp53 activates the Hippo pathway to promote cell death in response to DNA damage. Curr. Biol. 16 1453-8 PubMed GONUTS page
  7. Wells, BS et al. (2006) Compensatory proliferation in Drosophila imaginal discs requires Dronc-dependent p53 activity. Curr. Biol. 16 1606-15 PubMed GONUTS page
  8. Rebollar, E et al. (2006) Role of the p53 homologue from Drosophila melanogaster in the maintenance of histone H3 acetylation and response to UV-light irradiation. FEBS Lett. 580 642-8 PubMed GONUTS page
  9. Mandal, S et al. (2005) Mitochondrial regulation of cell cycle progression during development as revealed by the tenured mutation in Drosophila. Dev. Cell 9 843-54 PubMed GONUTS page
  10. McEwen, DG & Peifer, M (2005) Puckered, a Drosophila MAPK phosphatase, ensures cell viability by antagonizing JNK-induced apoptosis. Development 132 3935-46 PubMed GONUTS page
  11. 11.0 11.1 11.2 11.3 11.4 Zhang, B et al. (2015) The function of Drosophila p53 isoforms in apoptosis. Cell Death Differ. 22 2058-67 PubMed GONUTS page
  12. Merlo, P et al. (2014) p53 prevents neurodegeneration by regulating synaptic genes. Proc. Natl. Acad. Sci. U.S.A. 111 18055-60 PubMed GONUTS page
  13. Jassim, OW et al. (2003) Dmp53 protects the Drosophila retina during a developmentally regulated DNA damage response. EMBO J. 22 5622-32 PubMed GONUTS page
  14. 14.0 14.1 Brodsky, MH et al. (2004) Drosophila melanogaster MNK/Chk2 and p53 regulate multiple DNA repair and apoptotic pathways following DNA damage. Mol. Cell. Biol. 24 1219-31 PubMed GONUTS page
  15. Lee, JH et al. (2003) In vivo p53 function is indispensable for DNA damage-induced apoptotic signaling in Drosophila. FEBS Lett. 550 5-10 PubMed GONUTS page
  16. 16.0 16.1 Sogame, N et al. (2003) Drosophila p53 preserves genomic stability by regulating cell death. Proc. Natl. Acad. Sci. U.S.A. 100 4696-701 PubMed GONUTS page
  17. Zhang, B et al. (2014) Low levels of p53 protein and chromatin silencing of p53 target genes repress apoptosis in Drosophila endocycling cells. PLoS Genet. 10 e1004581 PubMed GONUTS page
  18. Barrio, L et al. (2014) MicroRNA-mediated regulation of Dp53 in the Drosophila fat body contributes to metabolic adaptation to nutrient deprivation. Cell Rep 8 528-41 PubMed GONUTS page
  19. Link, N et al. (2013) A p53 enhancer region regulates target genes through chromatin conformations in cis and in trans. Genes Dev. 27 2433-8 PubMed GONUTS page
  20. Villicaña, C et al. (2013) The genetic depletion or the triptolide inhibition of TFIIH in p53-deficient cells induces a JNK-dependent cell death in Drosophila. J. Cell. Sci. 126 2502-15 PubMed GONUTS page
  21. 21.0 21.1 Ouyang, Y et al. (2011) dp53 Restrains ectopic neural stem cell formation in the Drosophila brain in a non-apoptotic mechanism involving Archipelago and cyclin E. PLoS ONE 6 e28098 PubMed GONUTS page
  22. Chen, S et al. (2011) E2 ligase dRad6 regulates DMP53 turnover in Drosophila. J. Biol. Chem. 286 9020-30 PubMed GONUTS page
  23. 23.0 23.1 Brodsky, MH et al. (2000) Drosophila p53 binds a damage response element at the reaper locus. Cell 101 103-13 PubMed GONUTS page
  24. 24.0 24.1 Mesquita, D et al. (2010) A dp53-dependent mechanism involved in coordinating tissue growth in Drosophila. PLoS Biol. 8 e1000566 PubMed GONUTS page
  25. Bakhrat, A et al. (2010) Drosophila Chk2 and p53 proteins induce stage-specific cell death independently during oogenesis. Apoptosis 15 1425-34 PubMed GONUTS page
  26. 26.0 26.1 Lu, WJ et al. (2010) Meiotic recombination provokes functional activation of the p53 regulatory network. Science 328 1278-81 PubMed GONUTS page
  27. Fan, Y et al. (2010) Dual roles of Drosophila p53 in cell death and cell differentiation. Cell Death Differ. 17 912-21 PubMed GONUTS page
  28. 28.0 28.1 Schauer, T et al. (2009) Misregulated RNA Pol II C-terminal domain phosphorylation results in apoptosis. Cell. Mol. Life Sci. 66 909-18 PubMed GONUTS page
  29. 29.0 29.1 Hou, YC et al. (2008) Effector caspase Dcp-1 and IAP protein Bruce regulate starvation-induced autophagy during Drosophila melanogaster oogenesis. J. Cell Biol. 182 1127-39 PubMed GONUTS page
  30. Moon, NS et al. (2008) E2F and p53 induce apoptosis independently during Drosophila development but intersect in the context of DNA damage. PLoS Genet. 4 e1000153 PubMed GONUTS page
  31. Bereczki, O et al. (2008) TATA binding protein associated factor 3 (TAF3) interacts with p53 and inhibits its function. BMC Mol. Biol. 9 57 PubMed GONUTS page
  32. 32.0 32.1 Kumar, S (2000) Cell death in the fly comes of age. Cell Death Differ. 7 1021-4 PubMed GONUTS page
  33. 33.0 33.1 Richardson, H & Kumar, S (2002) Death to flies: Drosophila as a model system to study programmed cell death. J. Immunol. Methods 265 21-38 PubMed GONUTS page
  34. 34.0 34.1 Gorski, S & Marra, M (2002) Programmed cell death takes flight: genetic and genomic approaches to gene discovery in Drosophila. Physiol. Genomics 9 59-69 PubMed GONUTS page
  35. De Laurenzi, V & Melino, G (2000) Apoptosis. The little devil of death. Nature 406 135-6 PubMed GONUTS page
  36. Walworth, NC (2000) Cell-cycle checkpoint kinases: checking in on the cell cycle. Curr. Opin. Cell Biol. 12 697-704 PubMed GONUTS page