Your search keyword '"Baghdassarian H"' showing total 3 results

1. Combining LIANA and Tensor-cell2cell to decipher cell-cell communication across multiple samples.

Author

Baghdassarian H, Dimitrov D, Armingol E, Saez-Rodriguez J, and Lewis NE

Abstract

In recent years, data-driven inference of cell-cell communication has helped reveal coordinated biological processes across cell types. While multiple cell-cell communication tools exist, results are specific to the tool of choice, due to the diverse assumptions made across computational frameworks. Moreover, tools are often limited to analyzing single samples or to performing pairwise comparisons. As experimental design complexity and sample numbers continue to increase in single-cell datasets, so does the need for generalizable methods to decipher cell-cell communication in such scenarios. Here, we integrate two tools, LIANA and Tensor-cell2cell, which combined can deploy multiple existing methods and resources, to enable the robust and flexible identification of cell-cell communication programs across multiple samples. In this protocol, we show how the integration of our tools facilitates the choice of method to infer cell-cell communication and subsequently perform an unsupervised deconvolution to obtain and summarize biological insights. We explain how to perform the analysis step-by-step in both Python and R, and we provide online tutorials with detailed instructions available at https://ccc-protocols.readthedocs.io/. This protocol typically takes ~1.5h to complete from installation to downstream visualizations on a GPU-enabled computer, for a dataset of ~63k cells, 10 cell types, and 12 samples., Competing Interests: JSR reports funding from GSK, Pfizer and Sanofi and fees from Travere Therapeutics, and Astex. During the course of this work, NEL reports funding from Sanofi, Amgen, Sartorius, and Ionis, and is a co-founder of NeuImmune Inc. and Augment Biologics.

Published

2023

2. Inferring a spatial code of cell-cell interactions across a whole animal body.

Author

Armingol E, Ghaddar A, Joshi CJ, Baghdassarian H, Shamie I, Chan J, Her HL, Berhanu S, Dar A, Rodriguez-Armstrong F, Yang O, O'Rourke EJ, and Lewis NE

Subjects

Animals, Ligands, Communication, Phenotype, Caenorhabditis elegans, Cell Communication

Abstract

Cell-cell interactions shape cellular function and ultimately organismal phenotype. Interacting cells can sense their mutual distance using combinations of ligand-receptor pairs, suggesting the existence of a spatial code, i.e., signals encoding spatial properties of cellular organization. However, this code driving and sustaining the spatial organization of cells remains to be elucidated. Here we present a computational framework to infer the spatial code underlying cell-cell interactions from the transcriptomes of the cell types across the whole body of a multicellular organism. As core of this framework, we introduce our tool cell2cell, which uses the coexpression of ligand-receptor pairs to compute the potential for intercellular interactions, and we test it across the Caenorhabditis elegans' body. Leveraging a 3D atlas of C. elegans' cells, we also implement a genetic algorithm to identify the ligand-receptor pairs most informative of the spatial organization of cells across the whole body. Validating the spatial code extracted with this strategy, the resulting intercellular distances are negatively correlated with the inferred cell-cell interactions. Furthermore, for selected cell-cell and ligand-receptor pairs, we experimentally confirm the communicatory behavior inferred with cell2cell and the genetic algorithm. Thus, our framework helps identify a code that predicts the spatial organization of cells across a whole-animal body., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2022 Armingol et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2022

3. Learned adaptive multiphoton illumination microscopy for large-scale immune response imaging.

Author

Pinkard H, Baghdassarian H, Mujal A, Roberts E, Hu KH, Friedman DH, Malenica I, Shagam T, Fries A, Corbin K, Krummel MF, and Waller L

Subjects

Adaptive Immunity immunology, Algorithms, Animals, Antigens immunology, Female, Lymph Nodes metabolism, Machine Learning, Male, Mice, Inbred C57BL, Mice, Transgenic, Microscopy, Fluorescence, Multiphoton instrumentation, T-Lymphocytes immunology, T-Lymphocytes metabolism, Mice, Immunity immunology, Lymph Nodes immunology, Microscopy, Fluorescence, Multiphoton methods, Vaccination methods

Abstract

Multiphoton microscopy is a powerful technique for deep in vivo imaging in scattering samples. However, it requires precise, sample-dependent increases in excitation power with depth in order to generate contrast in scattering tissue, while minimizing photobleaching and phototoxicity. We show here how adaptive imaging can optimize illumination power at each point in a 3D volume as a function of the sample's shape, without the need for specialized fluorescent labeling. Our method relies on training a physics-based machine learning model using cells with identical fluorescent labels imaged in situ. We use this technique for in vivo imaging of immune responses in mouse lymph nodes following vaccination. We achieve visualization of physiologically realistic numbers of antigen-specific T cells (~2 orders of magnitude lower than previous studies), and demonstrate changes in the global organization and motility of dendritic cell networks during the early stages of the immune response. We provide a step-by-step tutorial for implementing this technique using exclusively open-source hardware and software.

Published

2021