TY - JOUR
T1 - Making life difficult for Clostridium difficile: augmenting the pathogen's metabolic model with transcriptomic and codon usage data for better therapeutic target characterization
AU - Kashaf, Sara S.
AU - Angione, Claudio
AU - Lió, Pietro
PY - 2017/2/16
Y1 - 2017/2/16
N2 - Background: Clostridium difficile is a bacterium which can infect various animal
species, including humans. Infection with this bacterium is a leading
healthcare-associated illness. A better understanding of this organism and the
relationship between its genotype and phenotype is essential to the search for an
effective treatment. Genome-scale metabolic models contain all known
biochemical reactions of a microorganism and can be used to investigate this
relationship.
Results: We present icdf834, an updated metabolic network of C. difficile that
builds on iMLTC806cdf and features 1227 reactions, 834 genes, and 807
metabolites. We used this metabolic network to reconstruct the metabolic
landscape of this bacterium. The standard metabolic model cannot account for
changes in the bacterial metabolism in response to different environmental
conditions. To account for this limitation, we also integrated transcriptomic data,
which details the gene expression of the bacterium in a wide array of
environments. Importantly, to bridge the gap between gene expression levels and
protein abundance, we accounted for the synonymous codon usage bias of the
bacterium in the model. To our knowledge, this is the first time codon usage has
been quantified and integrated into a metabolic model. The metabolic
uxes
were defined as a function of protein abundance. To determine potential
therapeutic targets using the model, we conducted gene essentiality and
metabolic pathway sensitivity analyses and calculated
ux control coefficients.
We obtained 92.3% accuracy in predicting gene essentiality when compared to
experimental data for C. difficile R20291 (ribotype 027) homologs. We validated
our context-specific metabolic models using sensitivity and robustness analyses
and compared model predictions with literature on C. difficile. The model
predicts interesting facets of the bacterium's metabolism, such as changes in the
bacterium's growth in response to different environmental conditions.
Conclusions: After an extensive validation process, we used icdf834 to obtain
state-of-the-art predictions of therapeutic targets for C. difficile. We show how
context-specific metabolic models augmented with codon usage information can
be a beneficial resource for better understanding C. difficile and for identifying
novel therapeutic targets. We remark that our approach can be applied to
investigate and treat against other pathogens.
AB - Background: Clostridium difficile is a bacterium which can infect various animal
species, including humans. Infection with this bacterium is a leading
healthcare-associated illness. A better understanding of this organism and the
relationship between its genotype and phenotype is essential to the search for an
effective treatment. Genome-scale metabolic models contain all known
biochemical reactions of a microorganism and can be used to investigate this
relationship.
Results: We present icdf834, an updated metabolic network of C. difficile that
builds on iMLTC806cdf and features 1227 reactions, 834 genes, and 807
metabolites. We used this metabolic network to reconstruct the metabolic
landscape of this bacterium. The standard metabolic model cannot account for
changes in the bacterial metabolism in response to different environmental
conditions. To account for this limitation, we also integrated transcriptomic data,
which details the gene expression of the bacterium in a wide array of
environments. Importantly, to bridge the gap between gene expression levels and
protein abundance, we accounted for the synonymous codon usage bias of the
bacterium in the model. To our knowledge, this is the first time codon usage has
been quantified and integrated into a metabolic model. The metabolic
uxes
were defined as a function of protein abundance. To determine potential
therapeutic targets using the model, we conducted gene essentiality and
metabolic pathway sensitivity analyses and calculated
ux control coefficients.
We obtained 92.3% accuracy in predicting gene essentiality when compared to
experimental data for C. difficile R20291 (ribotype 027) homologs. We validated
our context-specific metabolic models using sensitivity and robustness analyses
and compared model predictions with literature on C. difficile. The model
predicts interesting facets of the bacterium's metabolism, such as changes in the
bacterium's growth in response to different environmental conditions.
Conclusions: After an extensive validation process, we used icdf834 to obtain
state-of-the-art predictions of therapeutic targets for C. difficile. We show how
context-specific metabolic models augmented with codon usage information can
be a beneficial resource for better understanding C. difficile and for identifying
novel therapeutic targets. We remark that our approach can be applied to
investigate and treat against other pathogens.
U2 - 10.1186/s12918-017-0395-3
DO - 10.1186/s12918-017-0395-3
M3 - Article
SP - -
JO - BMC Systems Biology
JF - BMC Systems Biology
ER -