Alberto Sosa-Costa scite author profile

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Lateral Mobility and Nanoscale Spatial Arrangement of Chemokine-activated α4β1 Integrins on T Cells

Sosa-Costa

Val

Sevilla-Movilla

et al. 2016

Journal of Biological Chemistry

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Chemokine stimulation of integrin α4β1-dependent T lymphocyte adhesion is a key step during lymphocyte trafficking. A central question regarding α4β1 function is how its lateral mobility and organization influence its affinity and avidity following cell stimulation with chemokines and/or ligands. Using single particle tracking and superresolution imaging approaches, we explored the lateral mobility and spatial arrangement of individual α4β1integrins on T cells exposed to different activating stimuli. We show that CXCL12 stimulation leads to rapid and transient α4β1activation, measured by induction of the activation epitope recognized by the HUTS-21 anti-β1antibody and by increased talin-β1 association. CXCL12-dependent α4β1 activation directly correlated with restricted lateral diffusion and integrin immobilization. Moreover, co-stimulation by CXCL12 together with soluble VCAM-1 potentiated integrin immobilization with a 5-fold increase in immobile integrins compared with unstimulated conditions. Our data indicate that docking by talin of the chemokine-activated α4β1 to the actin cytoskeleton favors integrin immobilization, which likely facilitates ligand interaction and increased adhesiveness. Superresolution imaging showed that the nanoscale organization of high-affinity α4β1 remains unaffected following chemokine and/or ligand addition. Instead, newly activated α4β1 integrins organize on the cell membrane as independent units without joining pre-established integrin sites to contribute to cluster formation. Altogether, our results provide a rationale to understand how the spatiotemporal organization of activated α4β1 integrins regulates T lymphocyte adhesion.

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PLANT: A Method for Detecting Changes of Slope in Noisy Trajectories

Sosa-Costa

Piechocka

Gardini

et al. 2018

Biophysical Journal

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Time traces obtained from a variety of biophysical experiments contain valuable information on underlying processes occurring at the molecular level. Accurate quantification of these data can help explain the details of the complex dynamics of biological systems. Here, we describe PLANT (Piecewise Linear Approximation of Noisy Trajectories), a segmentation algorithm that allows the reconstruction of time-trace data with constant noise as consecutive straight lines, from which changes of slopes and their respective durations can be extracted. We present a general description of the algorithm and perform extensive simulations to characterize its strengths and limitations, providing a rationale for the performance of the algorithm in the different conditions tested. We further apply the algorithm to experimental data obtained from tracking the centroid position of lymphocytes migrating under the effect of a laminar flow and from single myosin molecules interacting with actin in a dual-trap force-clamp configuration.

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Shear flow-driven actin re-organization induces ICAM-1 nanoclustering on endothelial cells that impact T-cell migration

Piechocka

Keary

Sosa-Costa

et al. 2020

Preprint

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ABSTRACTThe leukocyte specific β2-integrin LFA-1, and its ligand ICAM-1 expressed on endothelial cells (ECs), are involved in the arrest, adhesion and transendothelial migration of leukocytes. Although the role of mechanical forces on LFA-1 activation is well established, the impact of forces on its major ligand ICAM-1, has received less attention. Using a parallel-plate flow chamber combined with confocal and super-resolution microscopy, we show that prolonged shear-flow induces a global translocation of ICAM-1 on ECs upstream of flow direction. Interestingly, shear-forces promoted ICAM-1 nanoclustering prior to LFA-1 engagement. This spatial nanoscale organization was driven by actin cytoskeleton re-arrangements induced by shear-force. We further assessed the impact of prolonged shear-stress EC stimulation on T cell migration. T cells adhered to mechanically pre-stimulated ECs developed a more pro-migratory phenotype, migrated faster and exhibited shorter EC interactions than when adhered to non-mechanically stimulated ECs. Together, our results indicate that shear-forces increase the number of ICAM-1/LFA-1 bonds due to ICAM-1 nanoclustering, strengthening adhesion and thereby reducing actin retrograde flow of T-cells, leading to their increased migration speed. Our data also underscores the importance of mechanical forces regulating the spatial organization of cell membrane receptors and their contribution to adhesion regulation, regardless of integrin activation.Summary statementWe show that shear forces promote ICAM-1 spatial re-arrangement and actin-dependent nanoclustering on ECs prior to integrin engagement. This mechanism might be important for firm leukocyte adhesion and migration during the immune response.

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