posted on 2016-02-22, 04:02authored byRui Li, James M. Tiedje, Chichia Chiu, R. Mark Worden
Shewanella species grow in widely disparate
environments
and play key roles in elemental cycling, especially in environments
with varied redox conditions. To obtain a system-level understanding
of Shewanella’s robustness and versatility,
the complex interplay of cellular growth, metabolism, and transport
under conditions of limiting carbon sources, energy sources, and electron
acceptors must be elucidated. In this paper, population-level taxis
of Shewanella oneidensis MR-1 cells in the presence
of a rate-limiting, insoluble electron acceptor was investigated.
A novel mechanism, mediated energy taxis, is proposed by which Shewanella use riboflavin as both an electron shuttle and
an attractant to direct cell movement toward local sources of insoluble
electron acceptors. The cells secrete reduced riboflavin, which diffuses
to a nearby particle containing an insoluble electron acceptor and
is oxidized. The oxidized riboflavin then diffuses away from the particle,
establishing a spatial gradient that draws cells toward the particle.
Experimental and modeling results are presented to support this mechanism. S. oneidensis MR-1 cells inoculated into a uniform dispersion
of MnO2 particles in dilute agar exhibited taxis outward,
creating a clear zone within which riboflavin was detected by mass
spectrometry. Cells inoculated into dilute agar containing oxidized
riboflavin similarly exhibited taxis, rapidly forming an expanding
zone of reduced riboflavin. A mathematical model based on the proposed
mechanism was able to predict experimental trends, including how concentrations
of riboflavin and insoluble electron acceptors (e.g., MnO2) affected tactic cell migration.