Affiliation:
1. School of Biology, Georgia Institute of Technology, Atlanta, Georgia, USA
Abstract
ABSTRACT
Shewanella oneidensis
is unable to metabolize the sugar xylose as a carbon and energy source. In the present study, an otherwise silent xylose catabolic pathway was activated in
S. oneidensis
by following an adaptive evolution strategy. Genome-wide scans indicated that the
S. oneidensis
genome encoded two proteins similar to the xylose oxido-reductase pathway enzymes xylose reductase (SO_0900) and xylulokinase (SO_4230), and purified SO_0900 and SO_4230 displayed xylose reductase and xylulokinase activities, respectively. The
S. oneidensis
genome was missing, however, an
Escherichia coli
XylE-like xylose transporter. After 12 monthly transfers in minimal growth medium containing successively higher xylose concentrations, an
S. oneidensis
mutant (termed strain XM1) was isolated for the acquired ability to grow aerobically on xylose as a carbon and energy source. Whole-genome sequencing indicated that strain XM1 contained a mutation in an unknown membrane protein (SO_1396) resulting in a glutamine-to-histidine conversion at amino acid position 207. Homology modeling demonstrated that the Q207H mutation in SO_1396 was located at the homologous xylose docking site in XylE. The expansion of the
S. oneidensis
metabolic repertoire to xylose expands the electron donors whose oxidation may be coupled to the myriad of terminal electron-accepting processes catalyzed by
S. oneidensis
. Since xylose is a lignocellulose degradation product, this study expands the potential substrates to include lignocellulosic biomass.
IMPORTANCE
The activation of an otherwise silent xylose metabolic system in
Shewanella oneidensis
is a powerful example of how accidental mutations allow microorganisms to adaptively evolve. The expansion of the
S. oneidensis
metabolic repertoire to xylose expands the electron donors whose oxidation may be coupled to the myriad of terminal electron-accepting processes catalyzed by
S. oneidensis
. Since xylose is a lignocellulose degradation product, this study expands the potential substrates to include lignocellulosic biomass.
Publisher
American Society for Microbiology
Subject
Ecology,Applied Microbiology and Biotechnology,Food Science,Biotechnology
Cited by
16 articles.
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