Chemogenomics and orthology‐based design of antibiotic combination therapies
Date
2016Author
Chandrasekaran, Sriram
Çokol-Çakmak, Melike
Şahin, Nil
Yılancıoğlu, Kaan
Kazan, Hilal
Collins, James J.
Çokol, Murat
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Show full item recordAbstract
Combination antibiotic therapies are being increasingly used in
the clinic to enhance potency and counter drug resistance.
However, the large search space of candidate drugs and dosage
regimes makes the identification of effective combinations highly
challenging. Here, we present a computational approach called
INDIGO, which uses chemogenomics data to predict antibiotic
combinations that interact synergistically or antagonistically in
inhibiting bacterial growth. INDIGO quantifies the influence of
individual chemical–genetic interactions on synergy and antagonism and significantly outperforms existing approaches based on
experimental evaluation of novel predictions in Escherichia coli.
Our analysis revealed a core set of genes and pathways (e.g.
central metabolism) that are predictive of antibiotic interactions.
By identifying the interactions that are associated with orthologous genes, we successfully estimated drug-interaction outcomes
in the bacterial pathogens Mycobacterium tuberculosis and Staphylococcus aureus, using the E. coli INDIGO model. INDIGO thus
enables the discovery of effective combination therapies in lessstudied pathogens by leveraging chemogenomics data in model
organisms.