A Model for Migratory B Cell Oscillations from Receptor Down-Regulation Induced by External Chemokine Fields

Chan, CP; Billard, Matthew J.; Ramirez, Samuel A.; Schmidl, Harald; Monson, Eric; Kepler, Thomas B.

doi:10.1007/s11538-012-9799-9

Cited by 15 publications

(14 citation statements)

References 37 publications

(50 reference statements)

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“…Diverse cells display different migratory modes. For example, amoeba move by repeatedly extending and retracting pseudopods, keratocytes glide with a single broad anterior protrusion, fibroblasts slowly project filopodia and lamellipodia with strong attachment, and some cells display oscillatory behavior 1 – 6 . Transitions between these migratory behaviors can be important, for example as cancer cells become metastatic 7 , 8 .…”

Section: Introductionmentioning

confidence: 99%

Altering the threshold of an excitable signal transduction network changes cell migratory modes

et al. 2017

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SUMMARY The diverse migratory modes displayed by different cell types are generally believed to be idiosyncratic. Here we show that the migratory behavior of Dictyostelium was switched from amoeboid to keratocyte-like and oscillatory modes by synthetically decreasing PIP2 levels or increasing Ras/Rap-related activities. The perturbations at these key nodes of an excitable signal transduction network initiated a causal chain of events: The threshold for network activation was lowered, the speed and range of propagating waves of signal transduction activity increased, actin driven cellular protrusions expanded and, consequently, the cell migratory mode transitions ensued. Conversely, innately keratocyte-like and oscillatory cells were promptly converted to amoeboid by inhibition of Ras effectors with restoration of directed migration. We use computational analysis to explain how thresholds control cell migration and discuss the architecture of the signal transduction network that gives rise to excitability.

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Section: Introductionmentioning

confidence: 99%

Altering the threshold of an excitable signal transduction network changes cell migratory modes

et al. 2017

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“…In particular, the model contains macrophages, dendritic cells, neutrophils, natural killer cells, B cells, T helper cells, complement proteins, and pathogenic bacteria. Reference [33] investigates a hypothesis about B cell hypermutation and affinity maturation using both individual particle-based stochastic and concentration-based non-spatial non-stochastic, ordinary differential equation models. A B cell model developed in [34] has partly similar ideas as our B cell model, but differs from MiStImm in the representation of ligands that are encoded by bit strings and their distances are measured by the number of mismatches (Hamming distance) (like in the above-mentioned IMMSIM and C-ImmSim models).…”

Section: Discussionmentioning

confidence: 99%

MiStImm: an agent-based simulation tool to study the self-nonself discrimination of the adaptive immune response

Kerepesi

Bakács

Szabados

2019

Theor Biol Med Model

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Background There is an increasing need for complex computational models to perform in silico experiments as an adjunct to in vitro and in vivo experiments in immunology. We introduce Microscopic Stochastic Immune System Simulator (MiStImm), an agent-based simulation tool, that is designed to study the self-nonself discrimination of the adaptive immune system. MiStImm can simulate some components of the humoral adaptive immune response, including T cells, B cells, antibodies, danger signals, interleukins, self cells, foreign antigens, and the interactions among them. The simulation starts after conception and progresses step by step (in time) driven by random simulation events. We also have provided tools to visualize and analyze the output of the simulation program. Results As the first application of MiStImm, we simulated two different immune models, and then we compared performances of them in the mean of self-nonself discrimination. The first model is a so-called conventional immune model, and the second model is based on our earlier T-cell model, called “one-signal model”, which is developed to resolve three important paradoxes of immunology. Our new T-cell model postulates that a dynamic steady state coupled system is formed through low-affinity complementary TCR–MHC interactions between T cells and host cells. The new model implies that a significant fraction of the naive polyclonal T cells is recruited into the first line of defense against an infection. Simulation experiments using MiStImm have shown that the computational realization of the new model shows real patterns. For example, the new model develops immune memory and it does not develop autoimmune reaction despite the hypothesized, enhanced TCR–MHC interaction between T cells and self cells. Simulations also demonstrated that our new model gives better results to overcome a critical primary infection answering the paradox “how can a tiny fraction of human genome effectively compete with a vastly larger pool of mutating pathogen DNA?” Conclusion The outcomes of our in silico experiments, presented here, are supported by numerous clinical trial observations from the field of immunotherapy. We hope that our results will encourage investigations to make in vitro and in vivo experiments clarifying questions about self-nonself discrimination of the adaptive immune system. We also hope that MiStImm or some concept in it will be useful to other researchers who want to implement or compare other immune models. Electronic supplementary material The online version of this article (10.1186/s12976-019-0105-5) contains supplementary material, which is available to authorized users.

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“…This has made the interpretation of imaging datasets in the context of the wider literature challenging. To address this issue, modeling approaches have been used to test the validity of different hypotheses of mechanisms controlling B-cell migration and selection within the GC (31–34). …”

Section: Case Study 2: Applying Mde To Understand Gc Dynamics and Funmentioning

confidence: 99%

Model-Driven Experimentation: A New Approach to Understand Mechanisms of Tertiary Lymphoid Tissue Formation, Function, and Therapeutic Resolution

et al. 2017

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The molecular and cellular processes driving the formation of secondary lymphoid tissues have been extensively studied using a combination of mouse knockouts, lineage-specific reporter mice, gene expression analysis, immunohistochemistry, and flow cytometry. However, the mechanisms driving the formation and function of tertiary lymphoid tissue (TLT) experimental techniques have proven to be more enigmatic and controversial due to differences between experimental models and human disease pathology. Systems-based approaches including data-driven biological network analysis (gene interaction network, metabolic pathway network, cell–cell signaling, and cascade networks) and mechanistic modeling afford a novel perspective from which to understand TLT formation and identify mechanisms that may lead to the resolution of tissue pathology. In this perspective, we make the case for applying model-driven experimentation using two case studies, which combined simulations with experiments to identify mechanisms driving lymphoid tissue formation and function, and then discuss potential applications of this experimental paradigm to identify novel therapeutic targets for TLT pathology.

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A Model for Migratory B Cell Oscillations from Receptor Down-Regulation Induced by External Chemokine Fields

Cited by 15 publications

References 37 publications

Altering the threshold of an excitable signal transduction network changes cell migratory modes

Altering the threshold of an excitable signal transduction network changes cell migratory modes

MiStImm: an agent-based simulation tool to study the self-nonself discrimination of the adaptive immune response

Model-Driven Experimentation: A New Approach to Understand Mechanisms of Tertiary Lymphoid Tissue Formation, Function, and Therapeutic Resolution

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