about
Role of autophagy in the maintenance and function of cancer stem cellsMolecular definitions of cell death subroutines: recommendations of the Nomenclature Committee on Cell Death 2012Essential versus accessory aspects of cell death: recommendations of the NCCD 2015.ATM kinase sustains breast cancer stem-like cells by promoting ATG4C expression and autophagy.Impact of the Ku complex on HIV-1 expression and latency.DNA Damage and Repair Biomarkers in Cervical Cancer Patients Treated with Neoadjuvant Chemotherapy: An Exploratory Analysis.Selective killing of p53-deficient cancer cells by SP600125.Body mass index modifies the relationship between γ-H2AX, a DNA damage biomarker, and pathological complete response in triple-negative breast cancer.Predictive significance of DNA damage and repair biomarkers in triple-negative breast cancer patients treated with neoadjuvant chemotherapy: An exploratory analysis.Whole-genome duplication increases tumor cell sensitivity to MPS1 inhibition.LTX-315, CAPtivating immunity with necrosis.Analysis of the hippo transducers TAZ and YAP in cervical cancer and its microenvironment.Predictive biomarkers for cancer therapy with PARP inhibitors.The Hippo transducers TAZ and YAP in breast cancer: oncogenic activities and clinical implications.Type-I-interferons in infection and cancer: Unanticipated dynamics with therapeutic implications.Cytofluorometric purification of diploid and tetraploid cancer cells.Involvement of p38alpha in the mitotic progression of p53(-/-) tetraploid cells.Preferential killing of tetraploid tumor cells by targeting the mitotic kinesin Eg5.The tubulin-depolymerising agent combretastatin-4 induces ectopic aster assembly and mitotic catastrophe in lung cancer cells H460.Combretastatin CA-4 and combretastatin derivative induce mitotic catastrophe dependent on spindle checkpoint and caspase-3 activation in non-small cell lung cancer cells.Analysis of the ATR-Chk1 and ATM-Chk2 pathways in male breast cancer revealed the prognostic significance of ATR expression.Guidelines for the use and interpretation of assays for monitoring cell death in higher eukaryotes.Immunosurveillance against cancer-associated hyperploidy.p53 represses the polyploidization of primary mammary epithelial cells by activating apoptosis.Replication stress in colorectal cancer stem cells.Molecular mechanisms of cell death: recommendations of the Nomenclature Committee on Cell Death 2018.Calcium signaling and cell cycle: Progression or death.DNA damage repair and survival outcomes in advanced gastric cancer patients treated with first-line chemotherapy.Molecular Regulation of the Spindle Assembly Checkpoint by Kinases and Phosphatases.Everybody In! No Bouncers at Tumor Gates.Synchronization and Desynchronization of Cells by Interventions on the Spindle Assembly Checkpoint.Driving to Cancer on a Four-Lane Expressway.Caspase 2 in mitotic catastrophe: The terminator of aneuploid and tetraploid cells.Spontaneous DNA damage propels tumorigenicity.Negative prognostic value of high levels of intracellular poly(ADP-ribose) in non-small cell lung cancer.Preferential killing of p53-deficient cancer cells by reversine.Chapter Eighteen Methods to Dissect Mitochondrial Membrane Permeabilization in the Course of ApoptosisReplication stress response in cancer stem cells as a target for chemotherapyCytofluorometric Quantification of Cell Death Elicited by NLR ProteinsThe clinical significance of PD-L1 in advanced gastric cancer is dependent on ARID1A mutations and ATM expression
P50
Q28081052-1854B048-426C-47F1-899D-4B9FBC633D0CQ29616161-B65EC63E-FD2C-4842-94BF-E633E38467EFQ30408769-1A657820-BC34-459C-960B-512E79A4EC75Q33591643-ED6809A4-1435-4023-9835-60EE9D2D2D5FQ34903532-59F8C1A8-2532-45B8-AC26-1CB8BD3208D7Q35941085-0CA91613-738B-49F1-8E1D-32823C387D37Q36238666-E771563C-9B35-40D3-932D-0BDE1EF96C92Q36272043-6FA2A751-6783-4EFC-B52A-9076D1AAF6D2Q36619000-5A590F37-3CDB-4567-85C5-E312E66DCEB0Q36729558-346E1E91-CBE8-4D63-9A00-D97CC0F538B1Q36957051-FD316443-9963-4FD8-9854-B513DB091E46Q37079126-FDAC5174-4F4D-45F2-993D-377E4D574FAAQ38137764-AF718D56-CAC0-4011-A558-8B319341CA73Q38542016-E7AED346-A535-4189-B56A-F7A89888FE8FQ39389626-7134C3CC-D268-4D64-9228-812A2D08F84FQ39507062-F662B737-F50C-4FF3-BD88-91218D865FA5Q39671109-48877138-CB75-4846-AA32-6AB83293A411Q39875569-A0C22FCF-5D22-446E-929A-32D3BC209BBDQ39995358-113F42BD-5385-4E0A-831C-C2A79B4FFB41Q40201178-8D2EFBB7-1DBF-4D3C-B233-7E545F40B2D9Q41388351-C8CF9CAC-413D-41A3-B462-8D84D5D7DB50Q41764481-57228F97-0EA4-44F1-8508-0E6E8B7B3763Q43083269-F98A2D3A-F3D7-4FF6-934B-D1F14E0CA5D7Q45374243-F552EE94-1319-46AC-98BF-E2B370D150AAQ47151796-2C46D71F-879B-4D89-8FCB-CB621C5DB881Q47843948-66E60B8C-6FCC-4D46-B20A-0D323DA13AEDQ47962930-E64C7CA2-FC8F-41C4-9A62-DCD92FAF4DFEQ48199486-1E9D9217-8D6D-47DD-855A-81BBBDB5BDCDQ48642636-0BC9833A-7E0B-4B15-AAC4-CE5416C7DE8AQ49579854-34F0B3F7-0A76-48C1-8EF9-708673749883Q51075833-A5F4476B-9708-411B-A597-C0E5C18703EDQ52763993-C4AE3BBA-FB4A-4127-BE80-698D4FCB8A00Q52765570-B27FF81C-4A4C-4AB8-9320-43987D182FC4Q53745588-72A8022D-F7AA-470A-990A-63212E329666Q53817080-3094D839-33BD-478B-8E9B-FA2E8E2D4975Q54510509-FB063276-5F6E-475A-AA6B-92063869C028Q57243776-61B27D9A-87B0-4281-8A66-B226FCDE66D5Q60201327-4D206D0F-C334-4E0C-907F-4AF786A374B8Q89277035-43A1E90A-7E3E-4835-9F29-11403DCBD655Q91473790-E179CE15-0DC6-47A8-A680-021B31B599CA
P50
description
researcher (ORCID 0000-0002-5918-1841)
@en
wetenschapper
@nl
name
Ilio Vitale
@en
Ilio Vitale
@nl
type
label
Ilio Vitale
@en
Ilio Vitale
@nl
prefLabel
Ilio Vitale
@en
Ilio Vitale
@nl
P31
P496
0000-0002-5918-1841