Quorum sensing via dynamic cytokine signaling comprehensively explains divergent patterns of effector choice among helper T cells

In the animal kingdom, various forms of swarming enable groups of autonomous individuals to transform uncertain information into unified decisions which are probabilistically beneficial. Crossing scales from individual to group decisions requires dynamically accumulating signals among individuals. I...

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Bibliographic Details
Published in:PLoS computational biology 2020-07, Vol.16 (7), p.e1008051-e1008051
Main Authors: Schrom, Edward C, Levin, Simon A, Graham, Andrea L
Format: Article
Language:English
Subjects:
Accumulation
Adaptive systems
Antigens
Biology and Life Sciences
CD4 antigen
CD4 lymphocytes
Cellular signal transduction
Coevolution
Computer and Information Sciences
Cytokines
Cytological research
Decision making
Detection
Divergence
Ecology
Evolutionary biology
Gene expression
Health aspects
Helper cells
Heterogeneity
Immune system
Immunology
Lymphatic system
Lymphocytes
Lymphocytes T
Mammals
Medicine and Health Sciences
Ordinary differential equations
Parasites
Physical Sciences
Quorum sensing
Signaling
Social Sciences
Structure
Swarming
Transcription factors
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Summary:In the animal kingdom, various forms of swarming enable groups of autonomous individuals to transform uncertain information into unified decisions which are probabilistically beneficial. Crossing scales from individual to group decisions requires dynamically accumulating signals among individuals. In striking parallel, the mammalian immune system is also a group of decentralized autonomous units (i.e. cells) which collectively navigate uncertainty with the help of dynamically accumulating signals (i.e. cytokines). Therefore, we apply techniques of understanding swarm behavior to a decision-making problem in the mammalian immune system, namely effector choice among CD4+ T helper (Th) cells. We find that incorporating dynamic cytokine signaling into a simple model of Th differentiation comprehensively explains divergent observations of this process. The plasticity and heterogeneity of individual Th cells, the tunable mixtures of effector types that can be generated in vitro, and the polarized yet updateable group effector commitment often observed in vivo are all explained by the same set of underlying molecular rules. These rules reveal that Th cells harness dynamic cytokine signaling to implement a system of quorum sensing. Quorum sensing, in turn, may confer adaptive advantages on the mammalian immune system, especially during coinfection and during coevolution with manipulative parasites. This highlights a new way of understanding the mammalian immune system as a cellular swarm, and it underscores the power of collectives throughout nature.
ISSN:1553-7358
1553-734X
1553-7358
DOI:10.1371/journal.pcbi.1008051