Kristopher D. Rawls scite author profile

The laboratory rat has been used as a surrogate to study human biology for more than a century. Here we present the first genome-scale network reconstruction of Rattus norvegicus metabolism, iRno, and a significantly improved reconstruction of human metabolism, iHsa. These curated models comprehensively capture metabolic features known to distinguish rats from humans including vitamin C and bile acid synthesis pathways. After reconciling network differences between iRno and iHsa, we integrate toxicogenomics data from rat and human hepatocytes, to generate biomarker predictions in response to 76 drugs. We validate comparative predictions for xanthine derivatives with new experimental data and literature-based evidence delineating metabolite biomarkers unique to humans. Our results provide mechanistic insights into species-specific metabolism and facilitate the selection of biomarkers consistent with rat and human biology. These models can serve as powerful computational platforms for contextualizing experimental data and making functional predictions for clinical and basic science applications.

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Identifying functional metabolic shifts in heart failure with the integration of omics data and a heart-specific, genome-scale model

Dougherty

Rawls

Kolling

et al. 2021

Cell Reports

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A simplified metabolic network reconstruction to promote understanding and development of flux balance analysis tools

Rawls

Dougherty

Blais

et al. 2019

Computers in Biology and Medicine

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Mechanistic identification of biofluid metabolite changes as markers of acetaminophen-induced liver toxicity in rats

Pannala

Vinnakota

Rawls

et al. 2019

Toxicology and Applied Pharmacology

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Acetaminophen (APAP) is the most commonly used analgesic and antipyretic drug in the world. Yet, it poses a major risk of liver injury when taken in excess of the therapeutic dose. Current clinical markers do not detect the early onset of liver injury associated with excess APAPinformation that is vital to reverse injury progression through available therapeutic interventions. Hence, several studies have used transcriptomics, proteomics, and metabolomics technologies, both independently and in combination, in an attempt to discover potential early markers of liver *

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Predicting changes in renal metabolism after compound exposure with a genome-scale metabolic model

Rawls

Dougherty

Vinnakota

et al. 2021

Toxicology and Applied Pharmacology

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