Your search keyword '"Noël, Floriane"' showing total 19 results

1. Global analysis of VHHs framework regions with a structural alphabet

Author

Noël, Floriane, Malpertuy, Alain, and De Brevern, Alexandre

Subjects

Quantitative Biology - Quantitative Methods, Quantitative Biology - Biomolecules

Abstract

The VHHs are antigen-binding region/domain of camelid heavy chain antibodies (HCAb). They have many interesting biotechnological and biomedical properties due to their small size, high solubility and stability, and high affinity and specificity for their antigens. HCAb and classical IgGs are evolutionary related and share a common fold. VHHs are composed of regions considered as constant, called the frameworks (FRs) connected by Complementarity Determining Regions (CDRs), a highly variable region that provide interaction with the epitope. Actually, no systematic structural analyses had been performed on VHH structures despite a significant number of structures. This work is the first study to analyse the structural diversity of FRs of VHHs. Using a structural alphabet that allows approximating the local conformation, we show that each of the four FRs do not have a unique structure but exhibit many structural variant patterns. Moreover, no direct simple link between the local conformational change and amino acid composition can be detected. These results indicate that long-range interactions affect the local conformation of FRs and impact the building of structural models.

Published

2016

2. Systems analysis of human T helper17 cell differentiation uncovers distinct time-regulated transcriptional modules

Author

Capone, Alessia, Naro, Chiara, Bianco, Manuela, De Bardi, Marco, Noël, Floriane, Macchi, Paolo, Battistini, Luca, Soumelis, Vassili, Volpe, Elisabetta, and Sette, Claudio

Published

2021

3. Dissection of intercellular communication using the transcriptome-based framework ICELLNET

Author

Noël, Floriane, Massenet-Regad, Lucile, Carmi-Levy, Irit, Cappuccio, Antonio, Grandclaudon, Maximilien, Trichot, Coline, Kieffer, Yann, Mechta-Grigoriou, Fatima, and Soumelis, Vassili

Published

2021

4. Biology and prognostic impact of clonal plasmacytoid dendritic cells in chronic myelomonocytic leukemia

Author

Lucas, Nolwenn, Duchmann, Matthieu, Rameau, Philippe, Noël, Floriane, Michea, Paula, Saada, Véronique, Kosmider, Olivier, Pierron, Gérard, Fernandez-Zapico, Martin E, Howard, Matthew T., King, Rebecca L., Niyongere, Sandrine, Diop, M’boyba Khadija, Fenaux, Pierre, Itzykson, Raphael, Willekens, Christophe, Ribrag, Vincent, Fontenay, Michaela, Padron, Eric, Soumelis, Vassili, Droin, Nathalie, Patnaik, Mrinal M, and Solary, Eric

Published

2019

5. Adjustment of dendritic cells to the breast-cancer microenvironment is subset specific

Author

Michea, Paula, Noël, Floriane, Zakine, Eve, Czerwinska, Urszula, Sirven, Philémon, Abouzid, Omar, Goudot, Christel, Scholer-Dahirel, Alix, Vincent-Salomon, Anne, Reyal, Fabien, Amigorena, Sebastian, Guillot-Delost, Maude, Segura, Elodie, and Soumelis, Vassili

Published

2018

6. Data from Meta-Analysis of Human Cancer Single-Cell RNA-Seq Datasets Using the IMMUcan Database

Author

Camps, Jordi, primary, Noël, Floriane, primary, Liechti, Robin, primary, Massenet-Regad, Lucile, primary, Rigade, Sidwell, primary, Götz, Lou, primary, Hoffmann, Caroline, primary, Amblard, Elise, primary, Saichi, Melissa, primary, Ibrahim, Mahmoud M., primary, Pollard, Jack, primary, Medvedovic, Jasna, primary, Roider, Helge G., primary, and Soumelis, Vassili, primary

Published

2023

7. Supplementary Data from Meta-Analysis of Human Cancer Single-Cell RNA-Seq Datasets Using the IMMUcan Database

Author

Camps, Jordi, primary, Noël, Floriane, primary, Liechti, Robin, primary, Massenet-Regad, Lucile, primary, Rigade, Sidwell, primary, Götz, Lou, primary, Hoffmann, Caroline, primary, Amblard, Elise, primary, Saichi, Melissa, primary, Ibrahim, Mahmoud M., primary, Pollard, Jack, primary, Medvedovic, Jasna, primary, Roider, Helge G., primary, and Soumelis, Vassili, primary

Published

2023

8. Meta-Analysis of Human Cancer Single-Cell RNA-Seq Datasets Using the IMMUcan Database

Author

Camps, Jordi, primary, Noël, Floriane, additional, Liechti, Robin, additional, Massenet-Regad, Lucile, additional, Rigade, Sidwell, additional, Götz, Lou, additional, Hoffmann, Caroline, additional, Amblard, Elise, additional, Saichi, Melissa, additional, Ibrahim, Mahmoud M., additional, Pollard, Jack, additional, Medvedovic, Jasna, additional, Roider, Helge G., additional, and Soumelis, Vassili, additional

Published

2022

9. Abstract 2105: PD-L1 high ICOSL low Secretory dendritic cells infiltrate human solid tumors

Author

Hoffmann, Caroline, primary, Noël, Floriane, additional, Grandclaudon, Maximilien, additional, Massenet-Regad, Lucile, additional, Michea, Paula, additional, Sirven, Philemon, additional, Faucheux, Lilith, additional, Surun, Aurore, additional, Lantz, Olivier, additional, Bohec, Mylene, additional, Ye, Jian, additional, Guo, Weihua, additional, Rochefort, Juliette, additional, Klijanienko, Jerzy, additional, Baulande, Sylvain, additional, Lecerf, Charlotte, additional, Kamal, Maud, additional, Tourneau, Christophe Le, additional, Guillot-Delost, Maude, additional, and Soumelis, Vassili, additional

Published

2022

10. Étude in silico de la communication intercellulaire avec ICELLNET

Author

Massenet-Regad, Lucile, primary, Noël, Floriane, additional, and Soumelis, Vassili, additional

Published

2021

11. Discrete analysis of camelid variable domains: sequences, structures, and in-silico structure prediction: Sequence-structure characteristics of VHH domains

Author

Melarkode Vattekatte, Akhila, Shinada, Nicolas Ken, Narwani, Tarun, Noël, Floriane, Bertrand, Olivier, Meyniel, Jean-Philippe, Malpertuy, Alain, Gelly, Jean-Christophe, Cadet, Frédéric, De Brevern, Alexandre, Université de La Réunion - Faculté des Sciences et Technologies (FST), Université de La Réunion (UR), Laboratoire d'Excellence : Biogenèse et pathologies du globule rouge (Labex Gr-Ex), Université Sorbonne Paris Cité (USPC)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Université de Paris (UP), Dynamique des Structures et Interactions des Macromolécules Biologiques - Pôle de La Réunion (DSIMB Réunion), Biologie Intégrée du Globule Rouge (BIGR (UMR_S_1134 / U1134)), Institut National de la Transfusion Sanguine [Paris] (INTS)-Université Paris Diderot - Paris 7 (UPD7)-Université de La Réunion (UR)-Université des Antilles (UA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut National de la Transfusion Sanguine [Paris] (INTS)-Université Paris Diderot - Paris 7 (UPD7)-Université de La Réunion (UR)-Université des Antilles (UA)-Institut National de la Santé et de la Recherche Médicale (INSERM), Institut National de la Transfusion Sanguine [Paris] (INTS)-Université de La Réunion (UR)-Institut National de la Santé et de la Recherche Médicale (INSERM)-CHU Pointe-à-Pitre/Abymes [Guadeloupe] -Université des Antilles (UA)-Université de Paris (UP), Services and solutions for Research Informatics [Paris] (Discngine), Discngine S.A.S [Paris], Institut National de la Transfusion Sanguine [Paris] (INTS), Immunité et cancer (U932), Institut Curie [Paris]-Institut National de la Santé et de la Recherche Médicale (INSERM), ISoft, Atragene (Atragene), Atragene, GR-Ex, Laboratoire d'Excellence, GR-Ex, PEACCEL, Ministry of Research (France)., University Paris Diderot, Sorbonne, Paris Cité (France)., Discngine, Paris, France., ANRT, France., Conseil Régional de la Réunion., The European Social Fund EU (ESF)., French National Computing Centre CINES under grant no. A0010707621 by the GENCI (Grand Equipement National de Calcul Intensif)., French National Computing Centre CINES under grant no. A0040710426 by the GENCI (Grand Equipement National de Calcul Intensif)., University of La Réunion, Réunion Island (France)., National Institute for Blood Transfusion (INTS, France)., National Institute for Health and Medical Research (INSERM, France)., Indo-French Centre for the Promotion of Advanced Research/CEFIPRA: 5302-2., ANR-18-IDEX-0001,Université de Paris,Université de Paris(2018), and ANR-11-IDEX-0005,USPC,Université Sorbonne Paris Cité(2011)

Subjects

Frameworks, Structural alphabet, [SDV]Life Sciences [q-bio], complementarity determining regions, Bioinformatics Keywords Secondary structure, Sequence structure relationship, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, secondary structure, Subjects Biochemistry, [SDV.BIBS]Life Sciences [q-bio]/Quantitative Methods [q-bio.QM], nanobodies, Antibodies

Abstract

International audience; Antigen binding by antibodies requires precise orientation of the complementarity- determining region (CDR) loops in the variable domain to establish the correct contact surface. Members of the family Camelidae have a modified form of immunoglobulin gamma (IgG) with only heavy chains, called Heavy Chain only Antibodies (HCAb). Antigen binding in HCAbs is mediated by only 3 CDR loops from the single variable domain (VHH) at the N-terminus of each heavy chain. This feature of the VHH, along with other important features, e.g. easy expression, small size, thermo-stability and hydrophilicity, made them promising candidates for therapeutics and diagnostics. Thus, to design better VHH domains, it is important to thoroughly understand their sequence and structure characteristics and relationships. In this study sequence, characteristics of VHH have been analysed in depth, along with their structural features using innovative approaches, namely a structural alphabet. An elaborate summary of various studies proposing structural models of VHHs showed diversity in the algorithms used. Finally, a case study to elucidate the differences in structural models from single and multiple templates is presented. In this case study, along with the above-mentioned aspects of VHH, an exciting view of various factors in structure prediction of VHH, like template framework selection, is also discussed.

Published

2020

12. ICELLNET: a transcriptome-based framework to dissect intercellular communication

Author

Noël, Floriane, primary, Massenet-Regad, Lucile, additional, Carmi-Levy, Irit, additional, Cappuccio, Antonio, additional, Grandclaudon, Maximilien, additional, Trichot, Coline, additional, Kieffer, Yann, additional, Mechta-Grigoriou, Fatima, additional, and Soumelis, Vassili, additional

Published

2020

13. Analyse systémique des sous-populations de cellules immunitaires et réseaux de communication intercellulaires dans les tumeurs du sein humaines

Author

Noël, Floriane, Immunité et cancer (U932), Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut Curie-Université Paris Descartes - Paris 5 (UPD5), Université Paris-Saclay, Vassili Soumelis, and Université Paris Descartes - Paris 5 (UPD5)-Institut Curie [Paris]-Institut National de la Santé et de la Recherche Médicale (INSERM)

Subjects

Cellules dendritiques, Immunology, Immunologie, Immunité antitumorale, Anti-tumor immunity, [SDV.IMM]Life Sciences [q-bio]/Immunology, Systems biology, Transcriptome, Dendritic cells, [SDV.BIBS]Life Sciences [q-bio]/Quantitative Methods [q-bio.QM], Biologie des systèmes

Abstract

Cell-to-cell communication is at the basis of the higher order organisation observed in tissues, organs, and organism. Understanding cell-to-cell communication, and its underlying mechanisms that drive the development of cancer is essential. Breast tumor microenvironment (TME) is composed of a great cellular diversity, such as endothelial, stromal or immune cells that can influence tumor progression as well as its response to treatment. Among the different immune cell populations, dendritic cells (DCs) subsets integrate signals from their microenvironment and are subsequently essential in orchestrating specific immune response through T cell activation. However, the differential function of these subsets, and their interactions within the TME remain poorly described. My main thesis objective was to understand the impact of the breast TME on DC subsets using systems-level analysis. We used RNA sequencing to systematically analyze the transcriptomes of tumor-infiltrating plasmacytoid pre-DCs (pDCs), cell populations enriched for type 1 classical DCs (cDC1e), type 2 classical DCs (cDC2s), CD14+DCs, and monocytes-macrophages from human primary luminal breast cancer and triple-negative breast cancer. We found that transcriptional reprogramming of tumor-infiltrating antigen-presenting cells is subset-specific. These results suggest a complex interplay between ontogeny and tissue imprinting in conditioning DC diversity and function in cancer.As a second objective, I aimed at studying the cellular communications in order to understand how cells integrate signals from their environment. I developed ICELLNET, a tool to reconstruct intercellular communication networks. This original quantitative method, integrating ligand-receptor interactions and cell type specific gene expression, can be automatically applied to any cell population level transcriptomic profile opening perspectives of application in several disease contexts and biology fields.; La communication intercellulaire est à la base de l'organisation d'ordre supérieur observée dans les tissus, les organes et l'organisme. Comprendre la communication intercellulaire et ses mécanismes sous-jacents qui sont impliqués dans le cancer est essentiel. Le microenvironnement des tumeurs du sein est composé d'une grande diversité cellulaire, telle que les cellules endothéliales, stromales ou immunitaires, qui peuvent influencer la progression tumorale ainsi que la réponse au traitement. Parmi les différentes populations de cellules immunitaires, les sous-populations de cellules dendritiques (DCs) intègrent les signaux du microenvironnement puis joue un rôle critique en orchestrant le développement d’une réponse immunitaire spécifique par activation des lymphocytes T. Cependant, les différentes fonctions de ces sous-populations et leurs interactions au sein du microenvironnement tumoral restent mal décrites. L’objectif principal de ma thèse a été de comprendre l'impact du microenvironnement tumorale du sein sur les sous-populations de DCs par analyse systémique. Nous avons utilisé le séquençage de l'ARN pour analyser systématiquement les transcriptomes des pré-DC plasmacytoïdes infiltrant les tumeurs (pDC), les populations cellulaires enrichies pour les DC classiques de type 1 (cDC1e), les DC classiques de type 2, les DC CD14+ et les monocytes-macrophages chez des patientes atteintes de cancer primitif du sein luminal et cancer du sein triple négatif. Nous avons constaté que la reprogrammation transcriptionnelle des cellules présentatrices d’antigène infiltrant la tumeur est spécifique à un sous-ensemble. Ces résultats suggèrent une interaction complexe entre l'ontogenèse et l'empreinte tissulaire dans le conditionnement de la diversité des DCs et de leur fonction dans le cancer.En second lieu, j'ai cherché à étudier les communications intercellulaires afin de comprendre comment les cellules intègrent les signaux de leur environnement. Nous avons développé ICELLNET, un outil pour reconstruire les réseaux de communication intercellulaires. Cette méthode quantitative originale, intégrant les interactions ligand-récepteur et l'expression génique spécifique à un type cellulaire, peut être appliquée automatiquement à tous profils transcriptomiques de population cellulaire, que ce soit dans divers contextes pathologiques ou d’autres domaines de la biologie.

Published

2018

14. Discrete analysis of camelid variable domains: sequences, structures, and in-silico structure prediction.

Author

Vattekatte, Akhila Melarkode, Ken Shinada, Nicolas, Narwani, Tarun J., Noël, Floriane, Bertrand, Olivier, Meyniel, Jean-Philippe, Malpertuy, Alain, Gelly, Jean-Christophe, Cadet, Frédéric, and de Brevern, Alexandre G.

Subjects

FORECASTING, STRUCTURAL models, FACTOR structure, CAMELIDAE

Abstract

Antigen binding by antibodies requires precise orientation of the complementaritydetermining region (CDR) loops in the variable domain to establish the correct contact surface. Members of the family Camelidae have a modified form of immunoglobulin gamma (IgG) with only heavy chains, called Heavy Chain only Antibodies (HCAb). Antigen binding in HCAbs is mediated by only three CDR loops from the single variable domain (VHH) at the N-terminus of each heavy chain. This feature of the VHH, along with their other important features, e.g., easy expression, small size, thermo-stability and hydrophilicity, made them promising candidates for therapeutics and diagnostics. Thus, to design better VHH domains, it is important to thoroughly understand their sequence and structure characteristics and relationship. In this study, sequence characteristics of VHH domains have been analysed in depth, along with their structural features using innovative approaches, namely a structural alphabet. An elaborate summary of various studies proposing structural models of VHHdomains showed diversity in the algorithms used. Finally, a case study to elucidate the differences in structural models from single and multiple templates is presented. In this case study, along with the above-mentioned aspects of VHH, an exciting view of various factors in structure prediction of VHH, like template framework selection, is also discussed. [ABSTRACT FROM AUTHOR]

Published

2020

15. Global analysis of VHHs framework regions with a structural alphabet

Author

Noël, Floriane, primary, Malpertuy, Alain, additional, and de Brevern, Alexandre G., additional

Published

2016

16. Meta-Analysis of Human Cancer Single-Cell RNA-Seq Datasets Using the IMMUcan Database.

Author

Camps J, Noël F, Liechti R, Massenet-Regad L, Rigade S, Götz L, Hoffmann C, Amblard E, Saichi M, Ibrahim MM, Pollard J, Medvedovic J, Roider HG, and Soumelis V

Subjects

Humans, Gene Expression Profiling, Sequence Analysis, RNA, Single-Cell Gene Expression Analysis, Single-Cell Analysis, Tumor Microenvironment genetics, Software, Neoplasms genetics

Abstract

The development of single-cell RNA sequencing (scRNA-seq) technologies has greatly contributed to deciphering the tumor microenvironment (TME). An enormous amount of independent scRNA-seq studies have been published representing a valuable resource that provides opportunities for meta-analysis studies. However, the massive amount of biological information, the marked heterogeneity and variability between studies, and the technical challenges in processing heterogeneous datasets create major bottlenecks for the full exploitation of scRNA-seq data. We have developed IMMUcan scDB (https://immucanscdb.vital-it.ch), a fully integrated scRNA-seq database exclusively dedicated to human cancer and accessible to nonspecialists. IMMUcan scDB encompasses 144 datasets on 56 different cancer types, annotated in 50 fields containing precise clinical, technological, and biological information. A data processing pipeline was developed and organized in four steps: (i) data collection; (ii) data processing (quality control and sample integration); (iii) supervised cell annotation with a cell ontology classifier of the TME; and (iv) interface to analyze TME in a cancer type-specific or global manner. This framework was used to explore datasets across tumor locations in a gene-centric (CXCL13) and cell-centric (B cells) manner as well as to conduct meta-analysis studies such as ranking immune cell types and genes correlated to malignant transformation. This integrated, freely accessible, and user-friendly resource represents an unprecedented level of detailed annotation, offering vast possibilities for downstream exploitation of human cancer scRNA-seq data for discovery and validation studies., Significance: The IMMUcan scDB database is an accessible supportive tool to analyze and decipher tumor-associated single-cell RNA sequencing data, allowing researchers to maximally use this data to provide new insights into cancer biology., (©2022 The Authors; Published by the American Association for Cancer Research.)

Published

2023

17. [In silico study of cell to cell communication with ICELLNET].

Author

Massenet-Regad L, Noël F, and Soumelis V

Subjects

Cell Communication, Computer Simulation

Published

2021

18. Discrete analysis of camelid variable domains: sequences, structures, and in-silico structure prediction.

Author

Melarkode Vattekatte A, Shinada NK, Narwani TJ, Noël F, Bertrand O, Meyniel JP, Malpertuy A, Gelly JC, Cadet F, and de Brevern AG

Abstract

Antigen binding by antibodies requires precise orientation of the complementarity- determining region (CDR) loops in the variable domain to establish the correct contact surface. Members of the family Camelidae have a modified form of immunoglobulin gamma (IgG) with only heavy chains, called Heavy Chain only Antibodies (HCAb). Antigen binding in HCAbs is mediated by only three CDR loops from the single variable domain (V H H) at the N-terminus of each heavy chain. This feature of the V H H, along with their other important features, e.g., easy expression, small size, thermo-stability and hydrophilicity, made them promising candidates for therapeutics and diagnostics. Thus, to design better V H H domains, it is important to thoroughly understand their sequence and structure characteristics and relationship. In this study, sequence characteristics of V H H domains have been analysed in depth, along with their structural features using innovative approaches, namely a structural alphabet. An elaborate summary of various studies proposing structural models of V H H domains showed diversity in the algorithms used. Finally, a case study to elucidate the differences in structural models from single and multiple templates is presented. In this case study, along with the above-mentioned aspects of V H H, an exciting view of various factors in structure prediction of V H H, like template framework selection, is also discussed., Competing Interests: Frederic Cadet is associated with PEACCEL, Paris, France. Jean-Christophe Gelly and Alexandre G. de Brevern are associated with IBL, Paris, France. Jean-Philippe Meyneil is employed by ISoft, Paris, France. Alain Malpertuy is employed by Atragene, Paris, France. Nicolas K. Shinada is sponsored by Discngine, Paris, France and ANRT, France. All other authors declare no competing interests., (©2020 Melarkode Vattekatte et al.)

Published

2020

19. Protein flexibility in the light of structural alphabets.

Author

Craveur P, Joseph AP, Esque J, Narwani TJ, Noël F, Shinada N, Goguet M, Leonard S, Poulain P, Bertrand O, Faure G, Rebehmed J, Ghozlane A, Swapna LS, Bhaskara RM, Barnoud J, Téletchéa S, Jallu V, Cerny J, Schneider B, Etchebest C, Srinivasan N, Gelly JC, and de Brevern AG

Abstract

Protein structures are valuable tools to understand protein function. Nonetheless, proteins are often considered as rigid macromolecules while their structures exhibit specific flexibility, which is essential to complete their functions. Analyses of protein structures and dynamics are often performed with a simplified three-state description, i.e., the classical secondary structures. More precise and complete description of protein backbone conformation can be obtained using libraries of small protein fragments that are able to approximate every part of protein structures. These libraries, called structural alphabets (SAs), have been widely used in structure analysis field, from definition of ligand binding sites to superimposition of protein structures. SAs are also well suited to analyze the dynamics of protein structures. Here, we review innovative approaches that investigate protein flexibility based on SAs description. Coupled to various sources of experimental data (e.g., B-factor) and computational methodology (e.g., Molecular Dynamic simulation), SAs turn out to be powerful tools to analyze protein dynamics, e.g., to examine allosteric mechanisms in large set of structures in complexes, to identify order/disorder transition. SAs were also shown to be quite efficient to predict protein flexibility from amino-acid sequence. Finally, in this review, we exemplify the interest of SAs for studying flexibility with different cases of proteins implicated in pathologies and diseases.

Published

2015