Título
Source and regulation of flux variability in Escherichia coliVersión
Version publicadaTipo de documento
ArtículoIdioma
InglésDerechos
© 2014 San Román et al.Acceso
Acceso abiertoVersión de la editorial
https://doi.org/10.1186/1752-0509-8-67Publicado en
BMC Systems Biology Vol. 8, n. art. 67Editorial
Springer Nature LinkPalabras clave
Metabolic network
Flux variability
Metabolic flexibility
Physiological adaptation ... [+]
Flux variability
Metabolic flexibility
Physiological adaptation ... [+]
Metabolic network
Flux variability
Metabolic flexibility
Physiological adaptation
Evolutionary adaptation
Systems biology [-]
Flux variability
Metabolic flexibility
Physiological adaptation
Evolutionary adaptation
Systems biology [-]
Resumen
Background: Metabolic responses are essential for the adaptation of microorganisms to changing environmental
conditions. The repertoire of flux responses that the metabolic network can display in dif ... [+]
Background: Metabolic responses are essential for the adaptation of microorganisms to changing environmental
conditions. The repertoire of flux responses that the metabolic network can display in different external conditions
may be quantified applying flux variability analysis to genome-scale metabolic reconstructions.
Results: A procedure is developed to classify and quantify the sources of flux variability. We apply the procedure to
the latest Escherichia coli metabolic reconstruction, in glucose minimal medium, with an additional constraint to
account for the mechanism coordinating carbon and nitrogen utilization mediated by α-ketoglutarate. Flux variability
can be decomposed into three components: internal, external and growth variability. Unexpectedly, growth variability
is the only significant component of flux variability in the physiological ranges of glucose, oxygen and ammonia uptake
rates. To obtain substantial increases in metabolic flexibility, E. coli must decrease growth rate to suboptimal values. This
growth-flexibility trade-off gives a straightforward interpretation to recent work showing that most overall cell-to-cell
flux variability in a population of E. coli can be attained sampling a small number of enzymes most likely to constrain
cell growth. Importantly, it provides an explanation for the global reorganization occurring in metabolic networks
during adaptations to environmental challenges. The calculations were repeated with a pathogenic strain and an
old reconstruction of the commensal strain, having less than 50% of the reactions of the latest reconstruction,
obtaining the same general conclusions.
Conclusions: In E. coli growing on glucose, growth variability is the only significant component of flux variability for
all physiological conditions explored. Increasing flux variability requires reducing growth to suboptimal values. The
growth-flexibility trade-off operates in physiological and evolutionary adaptations, and provides an explanation for
the global reorganization occurring during adaptations to environmental challenges. The results obtained do not rely
on the knowledge of kinetic and regulatory details of the system and are highly robust to incomplete or incorrect
knowledge of the reaction network [-]
Programa
PEDECIBA (Programa de Desarrollo de las Ciencias Básicas, Montevideo)ANII (Agencia Nacional de Investigación e Innovación, Montevideo)
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