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Your search keyword '"Pacheco, Maria Pires"' showing total 29 results
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29 results on '"Pacheco, Maria Pires"'

1. DCcov: Repositioning of Drugs and Drug Combinations for SARS-CoV-2 Infected Lung through Constraint-Based Modelling

Author

Kishk, Ali, Pacheco, Maria Pires, and Sauter, Thomas

Subjects
Quantitative Biology - Molecular Networks, Quantitative Biology - Genomics
Abstract

The 2019 coronavirus disease (COVID-19) became a worldwide pandemic with currently no effective antiviral drug except treatments for symptomatic therapy. Flux balance analysis is an efficient method to analyze metabolic networks. It allows optimizing for a metabolic function and thus e.g., predicting the growth rate of a specific cell or the production rate of a metabolite of interest. Here flux balance analysis was applied on human lung cells infected with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) to reposition metabolic drugs and drug combinations against the replication of the SARS-CoV-2 virus within the host tissue. Making use of expression data sets of infected lung tissue, genome-scale COVID-19-specific metabolic models were reconstructed. Then host-specific essential genes and gene-pairs were determined through in-silico knockouts that permit reducing the viral biomass production without affecting the host biomass. Key pathways that are associated with COVID-19 severity in lung tissue are related to oxidative stress, as well as ferroptosis, sphingolipid metabolism, cysteine metabolism, and fat digestion. By in-silico screening of FDA approved drugs on the putative disease-specific essential genes and gene-pairs, 45 drugs and 99 drug combinations were predicted as promising candidates for COVID-19 focused drug repositioning (https://github.com/sysbiolux/DCcov). Among the 45 drug candidates, six antiviral drugs were found and seven drugs that are being tested in clinical trials against COVID-19. Other drugs like gemcitabine, rosuvastatin and acetylcysteine, and drug combinations like azathioprine-pemetrexed might offer new chances for treating COVID-19.

Published
2021
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4. AMBRA1 levels predict resistance to MAPK inhibitors in melanoma.

Author

Di Leo, Luca, Pagliuca, Chiara, Kishk, Ali, Rizza, Salvatore, Tsiavou, Christina, Pecorari, Chiara, Dahl, Christina, Pacheco, Maria Pires, Tholstrup, Rikke, Brewer, Jonathan Richard, Berico, Pietro, Hernando, Eva, Cecconi, Francesco, Ballotti, Robert, Bertolotto, Corine, Filomeni, Giuseppe, Gjerstorff, Morten Frier, Sauter, Thomas, Lovat, Penny, and Guldberg, Per

Subjects
FOCAL adhesion kinase, MITOGEN-activated protein kinases, MELANOMA, PROTEIN kinase inhibitors
Abstract

Intrinsic and acquired resistance to mitogen-activated protein kinase inhibitors (MAPKi) in melanoma remains a major therapeutic challenge. Here, we show that the clinical development of resistance to MAPKi is associated with reduced tumor expression of the melanoma suppressor Autophagy and Beclin 1 Regulator 1 (AMBRA1) and that lower expression levels of AMBRA1 predict a poor response to MAPKi treatment. Functional analyses show that loss of AMBRA1 induces phenotype switching and orchestrates an extracellular signal-regulated kinase (ERK)-independent resistance mechanism by activating focal adhesion kinase 1 (FAK1). In both in vitro and in vivo settings, melanomas with low AMBRA1 expression exhibit intrinsic resistance to MAPKi therapy but higher sensitivity to FAK1 inhibition. Finally, we show that the rapid development of resistance in initially MAPKi-sensitive melanomas can be attributed to preexisting subclones characterized by low AMBRA1 expression and that cotreatment with MAPKi and FAK1 inhibitors (FAKi) effectively prevents the development of resistance in these tumors. In summary, our findings underscore the value of AMBRA1 expression for predicting melanoma response to MAPKi and supporting the therapeutic efficacy of FAKi to overcome MAPKi-induced resistance. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Towards the Integration of Metabolic Network Modelling and Machine Learning for the Routine Analysis of High-Throughput Patient Data

Author

Pacheco, Maria Pires, Bintener, Tamara, Sauter, Thomas, Crippen, Gordon, Advisory Editor, Dress, Andreas, Editor-in-Chief, Giegerich, Robert, Editorial Board Member, Kelso, Janet, Editorial Board Member, Linial, Michal, Editor-in-Chief, Felsenstein, Joseph, Advisory Editor, Troyanskaya, Olga, Editor-in-Chief, Gusfield, Dan, Advisory Editor, Myers, Gene, Editorial Board Member, Istrail, Sorin, Advisory Editor, Pevzner, Pavel, Editorial Board Member, Vingron, Martin, Editor-in-Chief, Lengauer, Thomas, Advisory Editor, McClure, Marcella, Advisory Editor, Nowak, Martin, Advisory Editor, Sankoff, David, Advisory Editor, Shamir, Ron, Advisory Editor, Steel, Mike, Advisory Editor, Stormo, Gary, Advisory Editor, Tavaré, Simon, Advisory Editor, Warnow, Tandy, Advisory Editor, Welch, Lonnie, Advisory Editor, Liò, Pietro, editor, and Zuliani, Paolo, editor

Published
2019
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6. Metabolic models predict fotemustine and the combination of eflornithine/rifamycin and adapalene/cannabidiol for the treatment of gliomas.

Author

Kishk, Ali, Pacheco, Maria Pires, Heurtaux, Tony, and Sauter, Thomas

Subjects
*METABOLIC models, *GLIOMAS, *GLIOBLASTOMA multiforme, *RIFAMYCINS, *CANNABIDIOL, *GLUTAMINE
Abstract

Gliomas are the most common type of malignant brain tumors, with glioblastoma multiforme (GBM) having a median survival of 15 months due to drug resistance and relapse. The treatment of gliomas relies on surgery, radiotherapy and chemotherapy. Only 12 anti-brain tumor chemotherapies (AntiBCs), mostly alkylating agents, have been approved so far. Glioma subtype–specific metabolic models were reconstructed to simulate metabolite exchanges, in silico knockouts and the prediction of drug and drug combinations for all three subtypes. The simulations were confronted with literature, high-throughput screenings (HTSs), xenograft and clinical trial data to validate the workflow and further prioritize the drug candidates. The three subtype models accurately displayed different degrees of dependencies toward glutamine and glutamate. Furthermore, 33 single drugs, mainly antimetabolites and TXNRD1-inhibitors, as well as 17 drug combinations were predicted as potential candidates for gliomas. Half of these drug candidates have been previously tested in HTSs. Half of the tested drug candidates reduce proliferation in cell lines and two-thirds in xenografts. Most combinations were predicted to be efficient for all three glioma types. However, eflornithine/rifamycin and cannabidiol/adapalene were predicted specifically for GBM and low-grade glioma, respectively. Most drug candidates had comparable efficiency in preclinical tests, cerebrospinal fluid bioavailability and mode-of-action to AntiBCs. However, fotemustine and valganciclovir alone and eflornithine and celecoxib in combination with AntiBCs improved the survival compared to AntiBCs in two-arms, phase I/II and higher glioma clinical trials. Our work highlights the potential of metabolic modeling in advancing glioma drug discovery, which accurately predicted metabolic vulnerabilities, repurposable drugs and combinations for the glioma subtypes. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Ambra1 modulates the tumor immune microenvironment and response to PD-1 blockade in melanoma

Author

Frias, Alex, primary, Di Leo, Luca, additional, Antoranz, Asier, additional, Nazerai, Loulieta, additional, Carretta, Marco, additional, Bodemeyer, Valérie, additional, Pagliuca, Chiara, additional, Dahl, Christina, additional, Claps, Giuseppina, additional, Mandelli, Giulio Eugenio, additional, Andhari, Madhavi Dipak, additional, Pacheco, Maria Pires, additional, Sauter, Thomas, additional, Robert, Caroline, additional, Guldberg, Per, additional, Madsen, Daniel Hargbøl, additional, Cecconi, Francesco, additional, Bosisio, Francesca Maria, additional, and De Zio, Daniela, additional

Published
2023
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8. Ambra1 modulates the tumor immune microenvironment and response to PD-1 blockade in melanoma

Author

Frias, Alex, Di Leo, Luca, Antoranz, Asier, Nazerai, Loulieta, Carretta, Marco, Bodemeyer, Valérie, Pagliuca, Chiara, Dahl, Christina, Claps, Giuseppina, Mandelli, Giulio Eugenio, Andhari, Madhavi Dipak, Pacheco, Maria Pires, Sauter, Thomas, Robert, Caroline, Guldberg, Per, Madsen, Daniel Hargbøl, Cecconi, Francesco, Bosisio, Francesca Maria, De Zio, Daniela, Frias, Alex, Di Leo, Luca, Antoranz, Asier, Nazerai, Loulieta, Carretta, Marco, Bodemeyer, Valérie, Pagliuca, Chiara, Dahl, Christina, Claps, Giuseppina, Mandelli, Giulio Eugenio, Andhari, Madhavi Dipak, Pacheco, Maria Pires, Sauter, Thomas, Robert, Caroline, Guldberg, Per, Madsen, Daniel Hargbøl, Cecconi, Francesco, Bosisio, Francesca Maria, and De Zio, Daniela

Abstract

BACKGROUND: Loss of Ambra1 (autophagy and beclin 1 regulator 1), a multifunctional scaffold protein, promotes the formation of nevi and contributes to several phases of melanoma development. The suppressive functions of Ambra1 in melanoma are mediated by negative regulation of cell proliferation and invasion; however, evidence suggests that loss of Ambra1 may also affect the melanoma microenvironment. Here, we investigate the possible impact of Ambra1 on antitumor immunity and response to immunotherapy.METHODS: This study was performed using an Ambra1-depleted BrafV600E /Pten-/ - genetically engineered mouse (GEM) model of melanoma, as well as GEM-derived allografts of BrafV600E /Pten-/ - and BrafV600E /Pten-/ -/Cdkn2a-/ - tumors with Ambra1 knockdown. The effects of Ambra1 loss on the tumor immune microenvironment (TIME) were analyzed using NanoString technology, multiplex immunohistochemistry, and flow cytometry. Transcriptome and CIBERSORT digital cytometry analyses of murine melanoma samples and human melanoma patients (The Cancer Genome Atlas) were applied to determine the immune cell populations in null or low-expressing AMBRA1 melanoma. The contribution of Ambra1 on T-cell migration was evaluated using a cytokine array and flow cytometry. Tumor growth kinetics and overall survival analysis in BrafV600E /Pten-/ -/Cdkn2a-/ - mice with Ambra1 knockdown were evaluated prior to and after administration of a programmed cell death protein-1 (PD-1) inhibitor.RESULTS: Loss of Ambra1 was associated with altered expression of a wide range of cytokines and chemokines as well as decreased infiltration of tumors by regulatory T cells, a subpopulation of T cells with potent immune-suppressive properties. These changes in TIME composition were associated with the autophagic function of Ambra1. In the BrafV600E /Pten-/ -/Cdkn2a-/ - model inherently resistant to immune checkpoint blockade, knockdown of Ambra1 led to accelerated tumor growth and reduced overall

Published
2023

19. Integrated In Vitro and In Silico Modeling Delineates the Molecular Effects of a Synbiotic Regimen on Colorectal-Cancer-Derived Cells

Author

Greenhalgh, Kacy, primary, Ramiro-Garcia, Javier, additional, Heinken, Almut, additional, Ullmann, Pit, additional, Bintener, Tamara, additional, Pacheco, Maria Pires, additional, Baginska, Joanna, additional, Shah, Pranjul, additional, Frachet, Audrey, additional, Halder, Rashi, additional, Fritz, Joëlle V., additional, Sauter, Thomas, additional, Thiele, Ines, additional, Haan, Serge, additional, Letellier, Elisabeth, additional, and Wilmes, Paul, additional

Published
2019
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21. Integrated in Vitro and in Silico Modelling Delineates the Molecular Effects of a Symbiotic Regimen on Colorectal Cancer-Derived Cells

Author

Greenhalgh, Kacy, primary, Ramiro-Garcia, Javier, additional, Heinken, Almut, additional, Ullmann, Pit, additional, Bintener, Tamara, additional, Pacheco, Maria Pires, additional, Baginska, Joanna, additional, Shah, Pranjul, additional, Frachet, Audrey, additional, Halder, Rashi, additional, Fritz, Joëlle V., additional, Sauter, Thomas, additional, Thiele, Ines, additional, Haan, Serge, additional, Letellier, Elisabeth, additional, and Wilmes, Paul, additional

Published
2018
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25. Towards improved genome-scale metabolic network reconstructions: unification, transcript specificity and beyond.

Author

Pfau, Thomas, Pacheco, Maria Pires, and Sauter, Thomas

Subjects
*GENE expression, *GENETIC regulation, *GENETIC transcription, *PROTON transfer reactions, *BIOINFORMATICS
Abstract

Genome-scale metabolic network reconstructions provide a basis for the investigation of the metabolic properties of an organism. There are reconstructions available for multiple organisms, from prokaryotes to higher organisms and methods for the analysis of a reconstruction. One example is the use of flux balance analysis to improve the yields of a target chemical, which has been applied successfully. However, comparison of results between existing reconstructions and models presents a challenge because of the heterogeneity of the available reconstructions, for example, of standards for presenting gene-protein-reaction associations, nomenclature of metabolites and reactions or selection of protonation states. The lack of comparability for gene identifiers or model-specific reactions without annotated evidence often leads to the creation of a new model from scratch, as data cannot be properly matched otherwise. In this contribution, we propose to improve the predictive power of metabolic models by switching from gene-protein-reaction associations to transcript-isoform-reaction associations, thus taking advantage of the improvement of precision in gene expression measurements. To achieve this precision, we discuss available databases that can be used to retrieve this type of information and point at issues that can arise from their neglect. Further, we stress issues that arise from non-standardized building pipelines, like inconsistencies in protonation states. In addition, problems arising from the use of non-specific cofactors, e.g. artificial futile cycles, are discussed, and finally efforts of the metabolic modelling community to unify model reconstructions are highlighted. [ABSTRACT FROM AUTHOR]

Published
2016
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26. Integrated In Vitroand In SilicoModeling Delineates the Molecular Effects of a Synbiotic Regimen on Colorectal-Cancer-Derived Cells

Author

Greenhalgh, Kacy, Ramiro-Garcia, Javier, Heinken, Almut, Ullmann, Pit, Bintener, Tamara, Pacheco, Maria Pires, Baginska, Joanna, Shah, Pranjul, Frachet, Audrey, Halder, Rashi, Fritz, Joëlle V., Sauter, Thomas, Thiele, Ines, Haan, Serge, Letellier, Elisabeth, and Wilmes, Paul

Abstract

By modulating the human gut microbiome, prebiotics and probiotics (combinations of which are called synbiotics) may be used to treat diseases such as colorectal cancer (CRC). Methodological limitations have prevented determining the potential combinatorial mechanisms of action of such regimens. We expanded our HuMiX gut-on-a-chip model to co-culture CRC-derived epithelial cells with a model probiotic under a simulated prebiotic regimen, and we integrated the multi-omic results with in silicometabolic modeling. In contrast to individual prebiotic or probiotic treatments, the synbiotic regimen caused downregulation of genes involved in procarcinogenic pathways and drug resistance, and reduced levels of the oncometabolite lactate. Distinct ratios of organic and short-chain fatty acids were produced during the simulated regimens. Treatment of primary CRC-derived cells with a molecular cocktail reflecting the synbiotic regimen attenuated self-renewal capacity. Our integrated approach demonstrates the potential of modeling for rationally formulating synbiotics-based treatments in the future.

Published
2019
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27. Epigenetic control of metabolic identity across cell types.

Author

Pacheco MP, Gerard D, Mangan RJ, Chapman AR, Hecker D, Kellis M, Schulz MH, Sinkkonen L, and Sauter T

Abstract

Constraint-based network modelling is a powerful tool for analysing cellular metabolism at genomic scale. Here, we conducted an integrative analysis of metabolic networks reconstructed from RNA-seq data with paired epigenomic data from the EpiATLAS resource of the International Human Epigenome Consortium (IHEC). Applying a state-of-the-art contextualisation algorithm, we reconstructed metabolic networks across 1,555 samples corresponding to 58 tissues and cell types. Analysis of these networks revealed the distribution of metabolic functionalities across human cell types and provides a compendium of human metabolic activity. This integrative approach allowed us to define, across tissues and cell types, i) reactions that fulfil the basic metabolic processes (core metabolism), and ii) cell type-specific functions (unique metabolism), that shape the metabolic identity of a cell or a tissue. Integration with EpiATLAS-derived cell type-specific gene-level chromatin states and enhancer-gene interactions identified enhancers, transcription factors, and key nodes controlling core and unique metabolism. Transport and first reactions of pathways were enriched for high expression, active chromatin state, and Polycomb-mediated repression in cell types where pathways are inactive, suggesting that key nodes are targets of repression. This integrative analysis forms the basis for identifying regulation points that control metabolic identity in human cells., Competing Interests: Competing interests The authors declare no competing interests.

Published
2024
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28. Drug Target Prediction Using Context-Specific Metabolic Models Reconstructed from rFASTCORMICS.

Author

Bintener T, Pacheco MP, Kishk A, Didier J, and Sauter T

Subjects
Computational Biology, Drug Repositioning, Humans, Workflow, Antineoplastic Agents therapeutic use, Neoplasms drug therapy
Abstract

Metabolic modeling is a powerful computational tool to analyze metabolism. It has not only been used to identify metabolic rewiring strategies in cancer but also to predict drug targets and candidate drugs for repurposing. Here, we will elaborate on the reconstruction of context-specific metabolic models of cancer using rFASTCORMICS and the subsequent prediction of drugs for repurposing using our drug prediction workflow., (© 2022. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2022
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29. The FASTCORE Family: For the Fast Reconstruction of Compact Context-Specific Metabolic Networks Models.

Author

Pacheco MP and Sauter T

Subjects
Algorithms, Animals, Humans, Models, Biological, Computational Biology methods, Metabolic Networks and Pathways
Abstract

The FASTCORE family is a family of algorithms that are mainly used to build context-specific models but can also be applied to other tasks such as gapfilling and consistency testing. The FASTCORE family has very low computational demands with running times that are several orders of magnitude lower than its main competitors. Furthermore, the models built by the FASTCORE family have a better resolution power (defined as the ability to capture metabolic variations between different tissues, cell types, or contexts) than models from other algorithms.

Published
2018
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