RT Journal Article
SR Electronic
T1 Linking light-dependent life history traits with population dynamics for <em>Prochlorococcus</em> and cyanophage
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 696435
DO 10.1101/696435
A1 David Demory
A1 Riyue Liu
A1 Yue Chen
A1 Fangxin Zhao
A1 Qinglu Zeng
A1 Joshua S. Weitz
YR 2019
UL http://biorxiv.org/content/early/2019/07/11/696435.abstract
AB Prochlorococcus grow in diurnal rhythms driven by diel cycles. Their ecology depends on light, nutrients, and top-down mortality processes including lysis by viruses. Cyanophage, viruses that infect cyanobacteria, are also impacted by light. For example, extracellular viability and intracell infection kinetics of some cyanophage vary between light and dark conditions. Nonetheless, it remains unclear if light-dependent viral life history traits scale-up to influence population-level dynamics. Here we examined the impact of diel-forcing on both cellular- and population-scale dynamics in multiple Prochlorococcus-phage systems. To do so, we developed a light-driven population model including both cellular growth and viral infection dynamics. We then tested the model against measurements of experimental infection dynamics with diel forcing to examine the extent to which population level changes in both viral and host abundances could be explained by light-dependent life history traits. Model-data integration reveals that light-dependent adsorption can improve fits to population dynamics for some virus-host pairs. However, light-dependent variation alone does not fully explain realized host and virus population dynamics. Instead, we show evidence of a previously unrecognized lysis saturation at relatively high virus to cell ratios. Altogether, our study represents a quantitative approach to integrate mechanistic models to reconcile Prochlorococcus-virus dynamics spanning cellular to population scales.