about
Guidelines for the use and interpretation of assays for monitoring autophagyExpression of dengue virus NS3 protein in Drosophila alters its susceptibility to infectionAdaptive preconditioning in neurological diseases – therapeutic insights from proteostatic perturbationsA DPP-mediated feed-forward loop canalizes morphogenesis during Drosophila dorsal closure.Wolbachia interferes with ferritin expression and iron metabolism in insectsFatty acid transport protein 1 regulates retinoid metabolism and photoreceptor development in mouse retina.Spalt transcription factors are required for R3/R4 specification and establishment of planar cell polarity in the Drosophila eye.Two-color in vivo imaging of photoreceptor apoptosis and development in DrosophilaGetting the better of ER stress.Biological functions of p53 isoforms through evolution: lessons from animal and cellular models.Photoreceptor differentiation in Drosophila: from immature neurons to functional photoreceptors.ER stress inhibits neuronal death by promoting autophagyDrosophila p53 isoforms differentially regulate apoptosis and apoptosis-induced proliferationER stress protects from retinal degenerationDisturbance of endoplasmic reticulum proteostasis in neurodegenerative diseases.The p53 control of apoptosis and proliferation: lessons from Drosophila.Drosophila Goosecoid requires a conserved heptapeptide for repression of paired-class homeoprotein activators.Fatty acid transport proteins in disease: New insights from invertebrate models.Rb-mediated apoptosis or proliferation: It's up to JNKThe Tomato/GFP-FLP/FRT method for live imaging of mosaic adult Drosophila photoreceptor cellsDrosophila fatty acid transport protein regulates rhodopsin-1 metabolism and is required for photoreceptor neuron survival.Establishing links between endoplasmic reticulum-mediated hormesis and cancer.p53-dependent programmed necrosis controls germ cell homeostasis during spermatogenesis.Compensatory proliferation and apoptosis-induced proliferation: a need for clarification.Cooling-Induced ER Stress is Good for Your BrainFirst International p53 Isoforms Meeting: 'p53 isoforms through evolution: from identification to biological function'Regulation of R7 and R8 differentiation by the spalt genes.Two-step process for photoreceptor formation in Drosophila.Munster, a novel paired-class homeobox gene specifically expressed in the Drosophila larval eye.Biophysical and genetic analysis of iron partitioning and ferritin function in Drosophila melanogaster.Cell death: what can we learn from flies? Editorial for the special review issue on Drosophila apoptosis.Spen is required for pigment cell survival during pupal development in Drosophila.DRP-1-mediated apoptosis induces muscle degeneration in dystrophin mutants.CD2-induced apoptosis in activated human peripheral T cells: a Fas-independent pathway that requires early protein tyrosine phosphorylationPromoting the clearance of neurotoxic proteins in neurodegenerative disorders of ageingA green fluorescent protein enhancer trap screen in Drosophila photoreceptor cellsEffects of anti-CD2 monoclonal antibody: CD2- and CD95-mediated apoptosis of human peripheral T cellsPotent apoptotic signaling and subsequent unresponsiveness induced by a single CD2 mAb (BTI-322) in activated human peripheral T cellsRelationship between proliferation and susceptibility to CD95- and CD2-mediated apoptosis in stimulated primary T lymphocytes: T cells manifesting proliferative unresponsiveness are preferentially susceptible to CD95-mediated apoptosisThiol-mediated inhibition of FAS and CD2 apoptotic signaling in activated human peripheral T cells
P50
Q21996341-6EE31757-6BF5-4288-8DCD-50612549DD75Q26314375-96D82121-FFE3-42A3-8478-DF3A876C8864Q26765956-D6E97C2C-7A7F-4B42-A25C-B88A35DB1EE1Q30616556-13099AAD-2A51-46CA-A673-D578447B2F87Q33511951-3BCE062A-5B7D-4041-940C-F4DE7AE2D3ACQ33865720-E62651CC-92F4-4D31-9E7A-7D40E10229E0Q33878307-C0E4EA19-52A4-4324-9CB4-874A7EE02232Q34636471-44368304-A7AB-46DE-83D9-4F7DEF025BD6Q35333412-763D73DA-C327-4BE1-B771-B1ECB71144D7Q35546335-86C4FD88-1B7E-49A3-A23F-AA9C54928F21Q36036909-BD010436-75FE-46B3-AFA7-FABDD7E95394Q36187772-2CCD218F-D635-4B89-89E7-93647B6D1D99Q36473588-D11D72A4-30FA-48C3-B61D-F394B3119483Q37194635-B3AF0E18-8E88-457D-9190-B75C1EFA8454Q38195215-A479FA5B-5AD3-456D-8B41-ED44C21CA1B4Q38248780-65028347-3C50-452A-A0BA-85E176F5C858Q38338059-BC77B320-89A3-41A8-9D17-6FAE11BA4F92Q38594883-B96F0AFC-795D-46CA-A9A8-B13C7D263E6AQ38640116-6391ACA8-26FD-4910-B41A-59EF4137E65DQ41886951-E371AD17-896B-48E8-BD95-7A1E620DFD3CQ42118593-F15E899B-4F2B-414E-9B50-1029BC23C022Q42259362-77955896-756E-4B9E-9BAB-C790F9A6AE7DQ42370922-25DD369B-66B7-40AC-86DA-0B244C509768Q42415092-4B6684B9-3D25-4CF3-A013-223CFE917DBAQ42514348-144E2CB4-AC98-4731-982C-C94FC2CC8865Q42790802-E1B289EC-0C33-4BC9-9553-1E48E7A3BCDFQ47072573-A1FB282C-0C06-4203-8840-403399A1618BQ47072576-AF6B4C61-25F5-4062-AF83-3BD8A8A34395Q47919111-99CA5484-0768-48D1-A699-2D78EC9B9FA0Q50903918-8E460B1A-82E5-4F49-9CF1-F0C030A6EE19Q52698362-85C12059-7576-4337-8F89-E6C75247FC13Q52799408-0B3BD1CA-3EE3-47F2-8571-74FD22DA1BEAQ55022386-E2317AAA-F019-4B02-A7B4-694006CD08F8Q57078493-0F555F6C-C659-4A99-9D5C-5B99844A9D5AQ57647180-54C08596-B6E5-42AB-B61C-3B19BBD80FD6Q57662295-4367D09F-DAC5-4102-9B90-D6B256A26524Q57662299-62D71B31-7D97-4D9C-80FA-888D73A73393Q57662302-9FA126BB-CE6E-4AF5-A45E-91622ECA987FQ57662305-7BBEC3CF-5FF6-4929-B6D3-9CB0325A1DB2Q57662310-8CF8ED4C-1479-4FB8-A2D9-FDD82D5800FF
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Bertrand Mollereau
@ast
Bertrand Mollereau
@en
Bertrand Mollereau
@es
Bertrand Mollereau
@nl
Bertrand Mollereau
@sl
type
label
Bertrand Mollereau
@ast
Bertrand Mollereau
@en
Bertrand Mollereau
@es
Bertrand Mollereau
@nl
Bertrand Mollereau
@sl
prefLabel
Bertrand Mollereau
@ast
Bertrand Mollereau
@en
Bertrand Mollereau
@es
Bertrand Mollereau
@nl
Bertrand Mollereau
@sl
P1053
S-4447-2017
P106
P21
P31
P496
0000-0003-4710-8185