A Model for Migratory B Cell Oscillations from Receptor Down-Regulation Induced by External Chemokine Fields
Authored by Cliburn Chan, Matthew Billard, Samuel A Ramirez, Harald Schmidl, Eric Monson, Thomas B Kepler
Date Published: 2013
DOI: 10.1007/s11538-012-9799-9
Sponsors:
United States National Institutes of Health (NIH)
Platforms:
No platforms listed
Model Documentation:
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Mathematical description
Model Code URLs:
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Abstract
A long-standing paradigm in B cell immunology is that effective somatic
hypermutation and affinity maturation require cycling between the dark
zone and light zone of the germinal center. The cyclic re-entry
hypothesis was first proposed based on considerations of the efficiency
of affinity maturation using an ordinary differential equations model
for B cell population dynamics. More recently, two-photon microscopy
studies of B cell motility within lymph nodes in situ have revealed the
complex migration patterns of B lymphocytes both in the preactivation
follicle and post-activation germinal center. There is strong evidence
that chemokines secreted by stromal cells and the regulation of cognate
G-protein coupled receptors by these chemokines are necessary for the
observed spatial cell distributions. For example, the distribution of B
cells within the light and dark zones of the germinal center appears to
be determined by the reciprocal interaction between the level of the
CXCR4 and CXCR5 receptors and the spatial distribution of their
respective chemokines CXCL12 and CXCL13. Computer simulations of
individual-based models have been used to study the complex biophysical
and mechanistic processes at the individual cell level, but such
simulations can be challenging to parameterize and analyze. In contrast, ordinary differential equations are more tractable, but traditional
compartment model formalizations ignore the spatial chemokine
distribution that drives B cell redistribution. Motivated by the desire
to understand the motility patterns observed in an individual-based
simulation of B cell migration in the lymph node, we propose and analyze
the dynamics of an ordinary differential equation model incorporating
explicit chemokine spatial distributions. While there is experimental
evidence that B cell migration patterns in the germinal center are
driven by extrinsically regulated differentiation programs, the model
shows, perhaps surprisingly, that feedback from receptor down-regulation
induced by external chemokine fields can give rise to spontaneous
interzonal and intrazonal oscillations in the absence of any extrinsic
regulation. While the extent to which such simple feedback mechanisms
contributes to B cell migration patterns in the germinal center is
unknown, the model provides an alternative hypothesis for how complex B
cell migration patterns might arise from very simple mechanisms.
Tags
Dynamics
Affinity maturation
Organization
Germinal center selection
Light zone
Modulation
Cxcr5
Ccr7
Determines
Follicles