Your search keyword '"Anna Chalari"' showing total 5 results

1. Kinome‐Wide Synthetic Lethal Screen Identifies PANK4 as a Modulator of Temozolomide Resistance in Glioblastoma

Author

Viviana Vella, Angeliki Ditsiou, Anna Chalari, Murat Eravci, Sarah K. Wooller, Teresa Gagliano, Cecilia Bani, Emanuela Kerschbamer, Christos Karakostas, Bin Xu, Yongchang Zhang, Frances M.G. Pearl, Gianluca Lopez, Ling Peng, Justin Stebbing, Apostolos Klinakis, and Georgios Giamas

Subjects

cellular detoxification, DUF89 domain, GBM, kinome‐wide RNAi screen, PANK4, TMT‐based quantitative proteomics, Science

Abstract

Abstract Temozolomide (TMZ) represents the cornerstone of therapy for glioblastoma (GBM). However, acquisition of resistance limits its therapeutic potential. The human kinome is an undisputable source of druggable targets, still, current knowledge remains confined to a limited fraction of it, with a multitude of under‐investigated proteins yet to be characterized. Here, following a kinome‐wide RNAi screen, pantothenate kinase 4 (PANK4) isuncovered as a modulator of TMZ resistance in GBM. Validation of PANK4 across various TMZ‐resistant GBM cell models, patient‐derived GBM cell lines, tissue samples, as well as in vivo studies, corroborates the potential translational significance of these findings. Moreover, PANK4 expression is induced during TMZ treatment, and its expression is associated with a worse clinical outcome. Furthermore, a Tandem Mass Tag (TMT)‐based quantitative proteomic approach, reveals that PANK4 abrogation leads to a significant downregulation of a host of proteins with central roles in cellular detoxification and cellular response to oxidative stress. More specifically, as cells undergo genotoxic stress during TMZ exposure, PANK4 depletion represents a crucial event that can lead to accumulation of intracellular reactive oxygen species (ROS) and subsequent cell death. Collectively, a previously unreported role for PANK4 in mediating therapeutic resistance to TMZ in GBM is unveiled.

Published

2024

2. Dengue Virus Replication Is Associated with Catecholamine Biosynthesis and Metabolism in Hepatocytes

Author

George Mpekoulis, Vassilina Tsopela, Anna Chalari, Katerina I. Kalliampakou, Georgios Panos, Efseveia Frakolaki, Raphaela S. Milona, Diamantis C. Sideris, Dido Vassilacopoulou, and Niki Vassilaki

Subjects

dengue virus replication, dopamine and norepinephrine biosynthesis, L-Dopa decarboxylase, dopamine beta-hydroxylase, catecholamine metabolism, vesicular monoamine transporter 2, Microbiology, QR1-502

Abstract

Previously, the association between the catecholamine biosynthetic enzyme L-Dopa decarboxylase (DDC) and Dengue virus (DV) replication was demonstrated in liver cells and was found to be mediated at least by the interaction between DDC and phosphoinositide 3-kinase (PI3K). Here, we show that biogenic amines production and uptake impede DV replication in hepatocytes and monocytes, while the virus reduces catecholamine biosynthesis, metabolism, and transport. To examine how catecholamine biosynthesis/metabolism influences DV, first, we verified the role of DDC by altering DDC expression. DDC silencing enhanced virus replication, but not translation, attenuated the negative effect of DDC substrates on the virus and reduced the infection related cell death. Then, the role of the downstream steps of the catecholamine biosynthesis/metabolism was analyzed by chemical inhibition of the respective enzymes, application of their substrates and/or their products; moreover, reserpine, the inhibitor of the vesicular monoamine transporter 2 (VMAT2), was used to examine the role of uptake/storage of catecholamines on DV. Apart from the role of each enzyme/transporter, these studies revealed that the dopamine uptake, and not the dopamine-signaling, is responsible for the negative effect on DV. Accordingly, all treatments expected to enhance the accumulation of catecholamines in the cell cytosol suppressed DV replication. This was verified by the use of chemical inducers of catecholamine biosynthesis. Last, the cellular redox alterations due to catecholamine oxidation were not related with the inhibition of DV replication. In turn, DV apart from its negative impact on DDC, inhibits tyrosine hydroxylase, dopamine beta-hydroxylase, monoamine oxidase, and VMAT2 expression.

Published

2022

3. Targeted Deletion of a Plasmodium Site-2 Protease Impairs Life Cycle Progression in the Mammalian Host.

Author

Konstantinos Koussis, Evi Goulielmaki, Anna Chalari, Chrislaine Withers-Martinez, Inga Siden-Kiamos, Kai Matuschewski, and Thanasis G Loukeris

Subjects

Medicine, Science

Abstract

Site-2 proteases (S2P) belong to the M50 family of metalloproteases, which typically perform essential roles by mediating activation of membrane-bound transcription factors through regulated intramembrane proteolysis (RIP). Protease-dependent liberation of dormant transcription factors triggers diverse cellular responses, such as sterol regulation, Notch signalling and the unfolded protein response. Plasmodium parasites rely on regulated proteolysis for controlling essential pathways throughout the life cycle. In this study we examine the Plasmodium-encoded S2P in a murine malaria model and show that it is expressed in all stages of Plasmodium development. Localisation studies by endogenous gene tagging revealed that in all invasive stages the protein is in close proximity to the nucleus. Ablation of PbS2P by reverse genetics leads to reduced growth rates during liver and blood infection and, hence, virulence attenuation. Strikingly, absence of PbS2P was compatible with parasite life cycle progression in the mosquito and mammalian hosts under physiological conditions, suggesting redundant or dispensable roles in vivo.

Published

2017

4. Kinome-wide synthetic lethal screen identifies PANK4 as modulator of resistance in glioblastoma

Author

Viviana Vella, Angeliki Ditsiou, Anna Chalari, Murat Eravci, Sarah K Wooler, Teresa Gagliano, Cecilia Bani, Emanuela Kerschbamer, Frances M.G. Pearl, Gianluca Lopez, Ling Peng, Justin Stebbing, Apostolos Klinakis, Georgios Giamas, Bin Xu, and Yongchang Zhang

Abstract

Temozolomide (TMZ) represents the cornerstone of therapy for glioblastoma (GBM). However, acquisition of resistance limits its therapeutic potential and therefore poses the need to identify new therapeutic combinations that could improve treatment outcomes. Despite the human kinome has proved to be an undisputable source of druggable targets, our knowledge remains confined to a limited fraction of it, with a multitude of under-investigated proteins yet to be characterised. Using a kinome-wide RNAi screen, we found that abrogation of pantothenate kinase 4 (PANK4) enhances the antiproliferative effects of TMZ in GBM in vitro. Further validation of our top-hit across various TMZ-resistant GBM cell models, patient-derived GBM cell lines and tissue samples, as well as in vivo studies, corroborated the potential translational significance of our findings. We showed that PANK4 expression is induced during TMZ treatment, and its expression is associated with a worse clinical outcome. Using a Tandem Mass Tag (TMT)-based quantitative proteomic approach, a comprehensive global protein dynamics analysis was undertaken to identify key response signatures upon PANK4 knockdown, in the presence or absence of TMZ. We revealed that silencing of PANK4 leads to a marked downregulation of a subset of proteins involved in cellular detoxification. More specifically, as cells undergo genotoxic stress during TMZ exposure, PANK4 depletion represents a synthetic vulnerability, focal point that can lead to critical cellular damage, accumulation of toxic metabolites, and subsequent cell death. Taken together, we unveil a previously unreported role for PANK4 in mediating therapeutic resistance to TMZ in GBM.

Published

2023

5. Loss of Kmt2c in vivo leads to EMT, mitochondrial dysfunction and improved response to lapatinib in breast cancer

Author

Nikiana Simigdala, Anna Chalari, Aimilia D. Sklirou, Evangelia Chavdoula, George Papafotiou, Pelagia Melissa, Aimilia Kafalidou, Nikolaos Paschalidis, Ioannis S. Pateras, Emmanouil Athanasiadis, Dimitris Konstantopoulos, Ioannis P. Trougakos, and Apostolos Klinakis

Subjects

Pharmacology, Cellular and Molecular Neuroscience, Molecular Medicine, Cell Biology, Molecular Biology

Abstract

Deep sequencing of human tumours has uncovered a previously unappreciated role for epigenetic regulators in tumorigenesis. H3K4 methyltransferase KMT2C/MLL3 is mutated in several solid malignancies, including more than 10% of breast tumours. To study the tumour suppressor role of KMT2C in breast cancer, we generated mouse models of Erbb2/Neu, Myc or PIK3CA-driven tumorigenesis, in which the Kmt2c locus is knocked out specifically in the luminal lineage of mouse mammary glands using the Cre recombinase. Kmt2c knock out mice develop tumours earlier, irrespective of the oncogene, assigning a bona fide tumour suppressor role for KMT2C in mammary tumorigenesis. Loss of Kmt2c induces extensive epigenetic and transcriptional changes, which lead to increased ERK1/2 activity, extracellular matrix re-organization, epithelial-to-mesenchymal transition and mitochondrial dysfunction, the latter associated with increased reactive oxygen species production. Loss of Kmt2c renders the Erbb2/Neu-driven tumours more responsive to lapatinib. Publicly available clinical datasets revealed an association of low Kmt2c gene expression and better long-term outcome. Collectively, our findings solidify the role of KMT2C as a tumour suppressor in breast cancer and identify dependencies that could be therapeutically amenable.

Published

2023