Your search keyword '"Marot-Lassauzaie, Valérie"' showing total 10 results

1. Identifying cancer cells from calling single-nucleotide variants in scRNA-seq data.

Author

Marot-Lassauzaie, Valérie, Beneyto-Calabuig, Sergi, Obermayer, Benedikt, Velten, Lars, Beule, Dieter, and Haghverdi, Laleh

Subjects

*ACUTE myeloid leukemia, *CLONE cells, *CANCER cells, *RNA sequencing, *RNA editing

Abstract

Motivation Single-cell RNA sequencing (scRNA-seq) data are widely used to study cancer cell states and their heterogeneity. However, the tumour microenvironment is usually a mixture of healthy and cancerous cells and it can be difficult to fully separate these two populations based on transcriptomics alone. If available, somatic single-nucleotide variants (SNVs) observed in the scRNA-seq data could be used to identify the cancer population and match that information with the single cells' expression profile. However, calling somatic SNVs in scRNA-seq data is a challenging task, as most variants seen in the short-read data are not somatic, but can instead be germline variants, RNA edits or transcription, sequencing, or processing errors. In addition, only variants present in actively transcribed regions for each individual cell will be seen in the data. Results To address these challenges, we develop CCLONE (Cancer Cell Labelling On Noisy Expression), an interpretable tool adapted to handle the uncertainty and sparsity of SNVs called from scRNA-seq data. CCLONE jointly identifies cancer clonal populations, and their associated variants. We apply CCLONE on two acute myeloid leukaemia datasets and one lung adenocarcinoma dataset and show that CCLONE captures both genetic clones and somatic events for multiple patients. These results show how CCLONE can be used to gather insight into the course of the disease and the origin of cancer cells in scRNA-seq data. Availability and implementation Source code is available at github.com/HaghverdiLab/CCLONE. [ABSTRACT FROM AUTHOR]

Published

2024

2. Identifying cancer cells from calling single-nucleotide variants in scRNA-seq data

Author

Marot-Lassauzaie, Valérie, primary, Beneyto-Calabuig, Sergi, additional, Obermayer, Benedikt, additional, Velten, Lars, additional, Beule, Dieter, additional, and Haghverdi, Laleh, additional

Published

2024

3. Single-cell time series analysis reveals the dynamics of HSPC response to inflammation.

Author

Bouman, Brigitte J., Demerdash, Yasmin, Sood, Shubhankar, Grünschlager, Florian, Pilz, Franziska, Itani, Abdul R., Kuck, Andrea, Marot-Lassauzaie, Valérie, Haas, Simon, Haghverdi, Laleh, and Essers, Marieke A. G.

Published

2024

4. P323: UNCOVERING SUBCLONAL METABOLIC VULNERABILITIES IN ACUTE LYMPHOBLASTIC LEUKEMIA AT SINGLE CELL RESOLUTION

Author

Mönnig, Maximilian, primary, Antes, Magdalena, additional, Beneyto-Calabuig, Sergi, additional, Vonficht, Dominik, additional, Marot-Lassauzaie, Valérie, additional, Besiriduo, Eleni, additional, Müller-Tidow, Carsten, additional, Haghverdi, Laleh, additional, Haas, Simon, additional, Velten, Lars, additional, and Raffel, Simon, additional

Published

2023

5. Towards reliable quantification of cell state velocities

Author

Marot-Lassauzaie, Valérie, primary, Bouman, Brigitte Joanne, additional, Donaghy, Fearghal Declan, additional, Demerdash, Yasmin, additional, Essers, Marieke Alida Gertruda, additional, and Haghverdi, Laleh, additional

Published

2022

6. Spectrum of Protein Location in Proteomes Captures Evolutionary Relationship Between Species

Author

Marot-Lassauzaie, Valérie, primary, Goldberg, Tatyana, additional, Armenteros, Jose Juan Almagro, additional, Nielsen, Henrik, additional, and Rost, Burkhard, additional

Published

2021

7. Spectrum of Protein Location in Proteomes Captures Evolutionary Relationship Between Species

Author

Marot-Lassauzaie, Valérie, Goldberg, Tatyana, Armenteros, Jose Juan Almagro, Nielsen, Henrik, Rost, Burkhard, Marot-Lassauzaie, Valérie, Goldberg, Tatyana, Armenteros, Jose Juan Almagro, Nielsen, Henrik, and Rost, Burkhard

Abstract

The native subcellular location (also referred to as localization or cellular compartment) of a protein is the one in which it acts most frequently; it is one aspect of protein function. Do ten eukaryotic model organisms differ in their location spectrum, i.e., the fraction of its proteome in each of seven major cellular compartments? As experimental annotations of locations remain biased and incomplete, we need prediction methods to answer this question. After systematic bias corrections, the complete but faulty prediction methods appeared to be more appropriate to compare location spectra between species than the incomplete more accurate experimental data. This work compared the location spectra for ten eukaryotes: Homo sapiens (human), Gorilla gorilla (gorilla), Pan troglodytes (chimpanzee), Mus musculus (mouse), Rattus norvegicus (rat), Drosophila melanogaster (fruit/vinegar fly), Anopheles gambiae (African malaria mosquito), Caenorhabitis elegans (nematode), Saccharomyces cerevisiae (baker’s yeast), and Schizosaccharomyces pombe (fission yeast). The two largest classes were predicted to be the nucleus and the cytoplasm together accounting for 47–62% of all proteins, while 7–21% of the proteins were predicted in the plasma membrane and 4–15% to be secreted. Overall, the predicted location spectra were largely similar. However, in detail, the differences sufficed to plot trees (UPGMA) and 2D (PCA) maps relating the ten organisms using a simple Euclidean distance in seven states (location classes). The relations based on the simple predicted location spectra captured aspects of cross-species comparisons usually revealed only by much more detailed evolutionary comparisons. Most interestingly, known phylogenetic relations were reproduced better by paralog-only than by ortholog-only trees.

Published

2021

8. Spectrum of protein localization in proteomes captures evolutionary relation between species

Author

Marot-Lassauzaie, Valérie, primary, Goldberg, Tatyana, additional, and Rost, Burkhard, additional

Published

2019

9. Correcting mistakes in predicting distributions

Author

Marot-Lassauzaie, Valérie, primary, Bernhofer, Michael, additional, and Rost, Burkhard, additional

Published

2018

10. Single-cell time series analysis reveals the dynamics of HSPC response to inflammation.

Author

Bouman BJ, Demerdash Y, Sood S, Grünschläger F, Pilz F, Itani AR, Kuck A, Marot-Lassauzaie V, Haas S, Haghverdi L, and Essers MA

Subjects

Humans, Time Factors, Cell Differentiation genetics, Inflammation metabolism, Hematopoietic Stem Cells, Hematopoiesis genetics

Abstract

Hematopoietic stem and progenitor cells (HSPCs) are known to respond to acute inflammation; however, little is understood about the dynamics and heterogeneity of these stress responses in HSPCs. Here, we performed single-cell sequencing during the sensing, response, and recovery phases of the inflammatory response of HSPCs to treatment (a total of 10,046 cells from four time points spanning the first 72 h of response) with the pro-inflammatory cytokine IFNα to investigate the HSPCs' dynamic changes during acute inflammation. We developed the essential novel computational approaches to process and analyze the resulting single-cell time series dataset. This includes an unbiased cell type annotation and abundance analysis post inflammation, tools for identification of global and cell type-specific responding genes, and a semi-supervised linear regression approach for response pseudotime reconstruction. We discovered a variety of different gene responses of the HSPCs to the treatment. Interestingly, we were able to associate a global reduced myeloid differentiation program and a locally enhanced pyroptosis activity with reduced myeloid progenitor and differentiated cells after IFNα treatment. Altogether, the single-cell time series analyses have allowed us to unbiasedly study the heterogeneous and dynamic impact of IFNα on the HSPCs., (© 2023 Bouman et al.)

Published

2023