Maša Ždralević
Šifra: 900647
Prezime i ime: Maša Ždralević
Titula: dr
Zvanje: saradnik u nastavi dr
Org. jedinica: Medicinski fakultet
Dopunski rad: ne
Honorarno: ne
Nastava
| Jedinica | Program | Tip | Sem. | Predmet | P x GP | V x GV | L x GL |
|---|
Izabrane publikacije
| Godina | Kategorija | Autori | Naslov | Izvor |
|---|---|---|---|---|
| 2020 | SCI, SCIE, SSCI, A&HCI | Elizabeth Mazzio, Ramesh Badisa, Nzinga Mack, Shamir Cassim, Masa Zdralevic, Jacques Pouyssegur, Karam F A Soliman | Whole-transcriptome Analysis of Fully Viable Energy Efficient Glycolytic-null Cancer Cells Established by Double Genetic Knockout of Lactate Dehydrogenase A/B or Glucose-6-Phosphate Isomerase | Cancer Genomics Proteomics |
| 2020 | SCI, SCIE, SSCI, A&HCI | Shamir Cassim, Milica Vučetić, Maša Ždralević and Jacques Pouyssegur | Warburg and Beyond: The Power of Mitochondrial Metabolism to Collaborate or Replace Fermentative Glycolysis in Cancer | Cancers |
| 2019 | SCOPUS | Pouysségur J, Ždralević M | Reply to Beltinger: Double genetic disruption of lactate dehydrogenases A and B is required to ablate the | J Biol Chem |
| 2018 | SCI, SCIE, SSCI, A&HCI | Ždralević M, Brand A, Di Ianni L, Dettmer K, Reinders J, Singer K, Peter K, Schnell A, Bruss C, Decking SM, Koehl G, Felipe-Abrio B, Durivault J, Bayer P, Evangelista M, O'Brien T, Oefner PJ, Renner K, Pouysségur J, Kreutz M | Double genetic disruption of lactate dehydrogenase A and B is required to ablate the 'Warburg effect' restricting tumor growth to oxidative metabolism | Journal of Biochemistry |
| 2018 | SCOPUS | Ždralević M, Vučetić M, Daher B, Marchiq I, Parks SK, Pouysségur J | Disrupting the 'Warburg effect' re-routes cancer cells to OXPHOS offering a vulnerability point via 'ferroptosis'-induced cell death | Adv Biol Regul |
| 2017 | SCI, SCIE, SSCI, A&HCI | Ždralević M, Marchiq I, de Padua MMC, Parks SK, Pouysségur J | Metabolic Plasiticy in Cancers-Distinct Role of Glycolytic Enzymes GPI, LDHs or Membrane Transporters MCTs | Frontiers in Oncology |
| 2017 | SCOPUS | de Padua MC, Delodi G, Vučetić M, Durivault J, Vial V, Bayer P, Noleto GR, Mazure NM, Ždralević M, Pouysségur J | Disrupting glucose-6-phosphate isomerase fully suppresses the "Warburg effect" and activates OXPHOS with minimal impact on tumor growth except in hypoxia | Oncotarget |
| 2016 | SCOPUS | Luna Laera, Nicoletta Guaragnella, Maša Ždralević, Domenico Marzulli, Zhengchang Liu, Sergio Giannattasio | The Transcription Factors ADR1 or CAT8 Are Required for RTG Pathway Activation and Evasion From Yeast Acetic Acid-Induced Programmed Cell Death in Raffinose | Microbial Cell |
| 2015 | SCI, SCIE, SSCI, A&HCI | Longo V, Ždralević M, Guaragnella N, Giannattasio S, Zolla L, Timperio AM | Proteome and metabolome profiling of wild-type and YCA1-knock-out yeast cells during acetic acid-induced programmed cell death | Journal of Proteomics |
| 2015 | SCOPUS | Ždralević M, Longo V, Guaragnella N, Giannattasio S, Timperio AM, Zolla L | Differential proteome-metabolome profiling of YCA1-knock-out and wild type cells reveals novel metabolic pathways and cellular processes dependent on the yeast metacaspase | Molecular BioSystems |
| 2015 | SCOPUS | Ždralević M, Guaragnella N, Giannattasio S | Yeast as a tool to study mitochondrial retrograde pathway en route to cell stress response | Methods in Molecular Biology |
| 2013 | SCI, SCIE, SSCI, A&HCI | Guaragnella N, Ždralević M, Lattanzio P, Marzulli D, Pracheil T, Liu Z, Passarella S, Marra E, Giannattasio S | Yeast growth in raffinose results in resistance to acetic-acid induced programmed cell death mostly due to the activation of the mitochondrial retrograde pathway | Biochimica et Biophysica Acta - Molecular Cell Research |
| 2013 | SCI, SCIE, SSCI, A&HCI | Giannattasio S, Guaragnella N, Zdralević M, Marra E | Molecular mechanisms of Saccharomyces cerevisiae stress adaptation and programmed cell death in response to acetic acid | Frontiers in Microbiology |
| 2012 | SCI, SCIE, SSCI, A&HCI | Antonacci L, Guaragnella N, Ždralevic M, Passarella S, Marra E, Giannattasio S | The N-acetylcysteine-insensitive acetic acid-induced yeast programmed cell death occurs without macroautophagy | Current Pharmaceutical Biotechnology |
| 2012 | SCI, SCIE, SSCI, A&HCI | Guaragnella N, Zdralević M, Antonacci L, Passarella S, Marra E, Giannattasio S | The role of mitochondria in yeast programmed cell death | Frontiers in Oncology |
| 2012 | SCOPUS | Zdralević M, Guaragnella N, Antonacci L, Marra E, Giannattasio S | Yeast as a tool to study signaling pathways in mitochondrial stress response and cytoprotection | The Scientific World Journal |
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Univerzitet Crne Gore. Sva prava zadržana.