TY - JOUR
T1 - Simulating CXCR5 Dynamics in Complex Tissue Microenvironments
AU - Cosgrove, Jason
AU - Alden, Kieran
AU - Stein, Jens V.
AU - Coles, Mark C.
AU - Timmis, Jon
N1 - Funding Information:
We wish to thank Antal Rot, Paul Kaye, Dimitris Lagos and members of the Hull/York Medical School for advice and reagents, the York Teaching Hospital NHS Foundation Trust R&D Department for invaluable assistance with sample collection protocol and Imaging & Cytometry Laboratory staff for technical input. The content of this manuscript has been published as part of the thesis of JC (53).
Funding Information:
KA was supported by Wellcome Trust Centre for Future Health grant (204829), JT by EPSRC grant EP/K040820/1. JC, JT, and MC were funded by Wellcome Trust (Computational Approaches in Translational Science WT0905024MA, HFSP
Publisher Copyright:
© Copyright © 2021 Cosgrove, Alden, Stein, Coles and Timmis.
PY - 2021/9/7
Y1 - 2021/9/7
N2 - To effectively navigate complex tissue microenvironments, immune cells sense molecular concentration gradients using G-protein coupled receptors. However, due to the complexity of receptor activity, and the multimodal nature of chemokine gradients in vivo, chemokine receptor activity in situ is poorly understood. To address this issue, we apply a modelling and simulation approach that permits analysis of the spatiotemporal dynamics of CXCR5 expression within an in silico B-follicle with single-cell resolution. Using this approach, we show that that in silico B-cell scanning is robust to changes in receptor numbers and changes in individual kinetic rates of receptor activity, but sensitive to global perturbations where multiple parameters are altered simultaneously. Through multi-objective optimization analysis we find that the rapid modulation of CXCR5 activity through receptor binding, desensitization and recycling is required for optimal antigen scanning rates. From these analyses we predict that chemokine receptor signaling dynamics regulate migration in complex tissue microenvironments to a greater extent than the total numbers of receptors on the cell surface.
AB - To effectively navigate complex tissue microenvironments, immune cells sense molecular concentration gradients using G-protein coupled receptors. However, due to the complexity of receptor activity, and the multimodal nature of chemokine gradients in vivo, chemokine receptor activity in situ is poorly understood. To address this issue, we apply a modelling and simulation approach that permits analysis of the spatiotemporal dynamics of CXCR5 expression within an in silico B-follicle with single-cell resolution. Using this approach, we show that that in silico B-cell scanning is robust to changes in receptor numbers and changes in individual kinetic rates of receptor activity, but sensitive to global perturbations where multiple parameters are altered simultaneously. Through multi-objective optimization analysis we find that the rapid modulation of CXCR5 activity through receptor binding, desensitization and recycling is required for optimal antigen scanning rates. From these analyses we predict that chemokine receptor signaling dynamics regulate migration in complex tissue microenvironments to a greater extent than the total numbers of receptors on the cell surface.
KW - B cells
KW - chemokines
KW - G-protein coupled receptors
KW - mathematical modelling
KW - systems biology
KW - Receptors, Chemokine/immunology
KW - Receptors, CXCR5/immunology
KW - Humans
KW - B-Lymphocytes/immunology
KW - Models, Immunological
KW - Cellular Microenvironment/immunology
KW - Signal Transduction/immunology
KW - Organ Specificity/immunology
UR - http://www.scopus.com/inward/record.url?scp=85115439010&partnerID=8YFLogxK
U2 - 10.3389/fimmu.2021.703088
DO - 10.3389/fimmu.2021.703088
M3 - Article
C2 - 34557191
AN - SCOPUS:85115439010
SN - 1664-3224
VL - 12
JO - Frontiers in Immunology
JF - Frontiers in Immunology
M1 - 703088
ER -