Emergence of increased frequency and severity of multiple infections by viruses due to spatial clustering of hosts
Authored by Bradford P Taylor, Catherine J Penington, Joshua S Weitz
Date Published: 2016
DOI: 10.1088/1478-3975/13/6/066014
Sponsors:
United States National Science Foundation (NSF)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
Multiple virus particles can infect a target host cell. Such multiple
infections (MIs) have significant and varied ecological and evolutionary
consequences for both virus and host populations. Yet, the in situ rates
and drivers of MIs in virus-microbe systems remain largely unknown.
Here, we develop an individual-based model (IBM) of virus-microbe
dynamics to probe how spatial interactions drive the frequency and
nature of MIs. In our IBMs, we identify increasingly spatially
correlated clusters of viruses given sufficient decreases in viral
movement. We also identify increasingly spatially correlated clusters of
viruses and clusters of hosts given sufficient increases in viral
infectivity. The emergence of clusters is associated with an increase in
multiply infected hosts as compared to expectations from an analogous
mean field model. We also observe long-tails in the distribution of the
multiplicity of infection in contrast to mean field expectations that
such events are exponentially rare. We show that increases in both the
frequency and severity of MIs occur when viruses invade a cluster of
uninfected microbes. We contend that population-scale enhancement of MI
arises from an aggregate of invasion dynamics over a distribution of
microbe cluster sizes. Our work highlights the need to consider
spatially explicit interactions as a potentially key driver underlying
the ecology and evolution of virus-microbe communities.
Tags
Evolution
Dynamics
bacteria
Habitats
Cells
Virulence
Abundance
Phage
Bacterioplankton
Lambda