Your search keyword '"Mary A. Schleiff"' showing total 16 results

1. The Role of Cytochrome P450 3A4-Mediated Metabolism in Sorafenib and Lapatinib Hepatotoxicity

Author

Mitchell R. McGill, Yihong Kaufmann, Francesca V. LoBianco, Mary A. Schleiff, Nukhet Aykin-Burns, and Grover P. Miller

Subjects

cancer, chemotherapy, drug-induced liver injury, drug metabolism, in vitro toxicology, Medicine (General), R5-920

Abstract

Tyrosine kinase inhibitors (TKIs) are increasingly popular drugs used to treat more than a dozen different diseases including some forms of cancer. Despite having fewer adverse effects than traditional chemotherapies, they are not without risks. Liver injury is a particular concern. Of the FDA-approved TKIs, approximately 40% cause hepatotoxicity. However, little is known about the underlying pathophysiology. The leading hypothesis is that TKIs are converted by cytochrome P450 3A4 (CYP3A4) to reactive metabolites that damage proteins. Indeed, there is strong evidence for this bioactivation of TKIs in in vitro reactions. However, the actual toxic effects are underexplored. Here, we measured the cytotoxicity of several TKIs in primary mouse hepatocytes, HepaRG cells and HepG2 cells with and without CYP3A4 modulation. To our surprise, the data indicate that CYP3A4 increases resistance to sorafenib and lapatinib hepatotoxicity. The results have implications for the mechanism of toxicity of these drugs in patients and underline the importance of selecting an appropriate experimental model.

Published

2023

2. Similar 5F-APINACA Metabolism between CD-1 Mouse and Human Liver Microsomes Involves Different P450 Cytochromes

Author

Samantha V. Crosby, Izzeldin Y. Ahmed, Laura R. Osborn, Zeyuan Wang, Mary A. Schleiff, William E. Fantegrossi, Swati Nagar, Paul L. Prather, Gunnar Boysen, and Grover P. Miller

Subjects

synthetic cannabinoid, 5F-APINACA, 5F-AKB48, P450, metabolism, enzyme kinetics, Microbiology, QR1-502

Abstract

In 2019, synthetic cannabinoids accounted for more than one-third of new drugs of abuse worldwide; however, assessment of associated health risks is not ethical for controlled and often illegal substances, making CD-1 mouse exposure studies the gold standard. Interpretation of those findings then depends on the similarity of mouse and human metabolic pathways. Herein, we report the first comparative analysis of steady-state metabolism of N-(1-adamantyl)-1-(5-pentyl)-1H-indazole-3-carboxamide (5F-APINACA/5F-AKB48) in CD-1 mice and humans using hepatic microsomes. Regardless of species, 5F-APINACA metabolism involved highly efficient sequential adamantyl hydroxylation and oxidative defluorination pathways that competed equally. Secondary adamantyl hydroxylation was less efficient for mice. At low 5F-APINACA concentrations, initial rates were comparable between pathways, but at higher concentrations, adamantyl hydroxylations became less significant due to substrate inhibition likely involving an effector site. For humans, CYP3A4 dominated both metabolic pathways with minor contributions from CYP2C8, 2C19, and 2D6. For CD-1 mice, Cyp3a11 and Cyp2c37, Cyp2c50, and Cyp2c54 contributed equally to adamantyl hydroxylation, but Cyp3a11 was more efficient at oxidative defluorination than Cyp2c members. Taken together, the results of our in vitro steady-state study indicate a high conservation of 5F-APINACA metabolism between CD-1 mice and humans, but deviations can occur due to differences in P450s responsible for the associated reactions.

Published

2022

3. Bioactivation of Isoxazole-Containing Bromodomain and Extra-Terminal Domain (BET) Inhibitors

Author

Noah R. Flynn, Michael D. Ward, Mary A. Schleiff, Corentine M. C. Laurin, Rohit Farmer, Stuart J. Conway, Gunnar Boysen, S. Joshua Swamidass, and Grover P. Miller

Subjects

bromodomain, inhibitor, isoxazole, model, deep neural network, pathway, Microbiology, QR1-502

Abstract

The 3,5-dimethylisoxazole motif has become a useful and popular acetyl-lysine mimic employed in isoxazole-containing bromodomain and extra-terminal (BET) inhibitors but may introduce the potential for bioactivations into toxic reactive metabolites. As a test, we coupled deep neural models for quinone formation, metabolite structures, and biomolecule reactivity to predict bioactivation pathways for 32 BET inhibitors and validate the bioactivation of select inhibitors experimentally. Based on model predictions, inhibitors were more likely to undergo bioactivation than reported non-bioactivated molecules containing isoxazoles. The model outputs varied with substituents indicating the ability to scale their impact on bioactivation. We selected OXFBD02, OXFBD04, and I-BET151 for more in-depth analysis. OXFBD’s bioactivations were evenly split between traditional quinones and novel extended quinone-methides involving the isoxazole yet strongly favored the latter quinones. Subsequent experimental studies confirmed the formation of both types of quinones for OXFBD molecules, yet traditional quinones were the dominant reactive metabolites. Modeled I-BET151 bioactivations led to extended quinone-methides, which were not verified experimentally. The differences in observed and predicted bioactivations reflected the need to improve overall bioactivation scaling. Nevertheless, our coupled modeling approach predicted BET inhibitor bioactivations including novel extended quinone methides, and we experimentally verified those pathways highlighting potential concerns for toxicity in the development of these new drug leads.

Published

2021

4. Significance of Competing Metabolic Pathways for 5F-APINACA Based on Quantitative Kinetics

Author

Anna O. Pinson, Dakota L. Pouncey, Mary A. Schleiff, William E. Fantegrossi, Paul L. Prather, Anna Radominska-Pandya, Gunnar Boysen, and Grover P. Miller

Subjects

synthetic cannabinoid, 5F-APINACA, 5F-AKB48, P450, kinetics, drug abuse, Organic chemistry, QD241-441

Abstract

In 2020, nearly one-third of new drugs on the global market were synthetic cannabinoids including the drug of abuse N-(1-adamantyl)-1-(5-pentyl)-1H-indazole-3-carboxamide (5F-APINACA, 5F-AKB48). Knowledge of 5F-APINACA metabolism provides a critical mechanistic basis to interpret and predict abuser outcomes. Prior qualitative studies identified which metabolic processes occur but not the order and extent of them and often relied on problematic “semi-quantitative” mass spectroscopic (MS) approaches. We capitalized on 5F-APINACA absorbance for quantitation while leveraging MS to characterize metabolite structures for measuring 5F-APINACA steady-state kinetics. We demonstrated the reliability of absorbance and not MS for inferring metabolite levels. Human liver microsomal reactions yielded eight metabolites by MS but only five by absorbance. Subsequent kinetic studies on primary and secondary metabolites revealed highly efficient mono- and dihydroxylation of the adamantyl group and much less efficient oxidative defluorination at the N-pentyl terminus. Based on regiospecificity and kinetics, we constructed pathways for competing and intersecting steps in 5F-APINACA metabolism. Overall efficiency for adamantyl oxidation was 17-fold higher than that for oxidative defluorination, showing significant bias in metabolic flux and subsequent metabolite profile compositions. Lastly, our analytical approach provides a powerful new strategy to more accurately assess metabolic kinetics for other understudied synthetic cannabinoids possessing the indazole chromophore.

Published

2020

5. The Role of Cytochrome P450 3A4-Mediated Metabolism in Sorafenib and Lapatinib Hepatotoxicity

Author

Miller, Mitchell R. McGill, Yihong Kaufmann, Francesca V. LoBianco, Mary A. Schleiff, Nukhet Aykin-Burns, and Grover P.

Subjects

cancer, chemotherapy, drug-induced liver injury, drug metabolism, in vitro toxicology

Abstract

Tyrosine kinase inhibitors (TKIs) are increasingly popular drugs used to treat more than a dozen different diseases including some forms of cancer. Despite having fewer adverse effects than traditional chemotherapies, they are not without risks. Liver injury is a particular concern. Of the FDA-approved TKIs, approximately 40% cause hepatotoxicity. However, little is known about the underlying pathophysiology. The leading hypothesis is that TKIs are converted by cytochrome P450 3A4 (CYP3A4) to reactive metabolites that damage proteins. Indeed, there is strong evidence for this bioactivation of TKIs in in vitro reactions. However, the actual toxic effects are underexplored. Here, we measured the cytotoxicity of several TKIs in primary mouse hepatocytes, HepaRG cells and HepG2 cells with and without CYP3A4 modulation. To our surprise, the data indicate that CYP3A4 increases resistance to sorafenib and lapatinib hepatotoxicity. The results have implications for the mechanism of toxicity of these drugs in patients and underline the importance of selecting an appropriate experimental model.

Published

2023

6. Significance of Multiple Bioactivation Pathways for Meclofenamate as Revealed through Modeling and Reaction Kinetics

Author

Benjamin Mark Schleiff, Grover P. Miller, Sasin Payakachat, Dennis W. Province, Noah R. Flynn, Gunnar Boysen, S. Joshua Swamidass, Anna O. Pinson, and Mary A. Schleiff

Subjects

Pharmaceutical Science, Pharmacology, 030226 pharmacology & pharmacy, Mass Spectrometry, Activation, Metabolic, Chemical kinetics, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Benzoquinones, Humans, Enzyme kinetics, Meclofenamic Acid, Nonsteroidal, Human liver, Chemistry, Mechanism (biology), Anti-Inflammatory Agents, Non-Steroidal, Articles, Glutathione, Spectrometry, Fluorescence, Models, Chemical, 030220 oncology & carcinogenesis, Reactive metabolite, Microsomes, Liver, Total metabolism, Chromatography, Liquid

Abstract

Meclofenamate is a nonsteroidal anti-inflammatory drug used in the treatment of mild-to-moderate pain yet poses a rare risk of hepatotoxicity through an unknown mechanism. Nonsteroidal anti-inflammatory drug (NSAID) bioactivation is a common molecular initiating event for hepatotoxicity. Thus, we hypothesized a similar mechanism for meclofenamate and leveraged computational and experimental approaches to identify and characterize its bioactivation. Analyses employing our XenoNet model indicated possible pathways to meclofenamate bioactivation into 19 reactive metabolites subsequently trapped into glutathione adducts. We describe the first reported bioactivation kinetics for meclofenamate and relative importance of those pathways using human liver microsomes. The findings validated only four of the many bioactivation pathways predicted by modeling. For experimental studies, dansyl glutathione was a critical trap for reactive quinone metabolites and provided a way to characterize adduct structures by mass spectrometry and quantitate yields during reactions. Of the four quinone adducts, we were able to characterize structures for three of them. Based on kinetics, the most efficient bioactivation pathway led to the monohydroxy para-quinone-imine followed by the dechloro-ortho-quinone-imine. Two very inefficient pathways led to the dihydroxy ortho-quinone and a likely multiply adducted quinone. When taken together, bioactivation pathways for meclofenamate accounted for approximately 13% of total metabolism. In sum, XenoNet facilitated prediction of reactive metabolite structures, whereas quantitative experimental studies provided a tractable approach to validate actual bioactivation pathways for meclofenamate. Our results provide a foundation for assessing reactive metabolite load more accurately for future comparative studies with other NSAIDs and drugs in general. Significance Statement Meclofenamate bioactivation may initiate hepatotoxicity, yet common risk assessment approaches are often cumbersome and inefficient and yield qualitative insights that do not scale relative bioactivation risks. We developed and applied innovative computational modeling and quantitative kinetics to identify and validate meclofenamate bioactivation pathways and relevance as a function of time and concentration. This strategy yielded novel insights on meclofenamate bioactivation and provides a tractable approach to more accurately and efficiently assess other drug bioactivations and correlate risks to toxicological outcomes.

Published

2020

7. Advances in the study of drug metabolism – symposium report of the 12th Meeting of the International Society for the Study of Xenobiotics (ISSX)

Author

Chukwunonso K Nwabufo, Iain Martin, Matthew Segall, Fabio Broccatelli, Emily E. Scott, Eric Gonzalez, Jasleen K. Sodhi, Laura E Russell, Aaron G. Bart, Mary A. Schleiff, W. Griffith Humphreys, Ryan H. Takahashi, Mitchell E. Taub, Volker M. Lauschke, Bhagwat Prasad, and Jessica H. Hartman

Subjects

business.industry, Computational Biology, Congresses as Topic, 030226 pharmacology & pharmacy, Article, Xenobiotics, Machine Learning, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Pharmaceutical Preparations, chemistry, Biochemistry, 030220 oncology & carcinogenesis, Drug Discovery, Quantum Theory, Medicine, Pharmacology (medical), General Pharmacology, Toxicology and Pharmaceutics, Pharmaceutical sciences, Xenobiotic, business, human activities, Drug metabolism

Abstract

The 12(th) International Society for the Study of Xenobiotics (ISSX) meeting, held in Portland, OR, USA from July 28–31, 2019, was attended by diverse members of the pharmaceutical sciences community. The ISSX New Investigators Group provides learning and professional growth opportunities for student and early career members of ISSX. To share meeting content with those who were unable to attend, the ISSX New Investigators herein elected to highlight the “Advances in the Study of Drug Metabolism” symposium, as it engaged attendees with diverse backgrounds. This session covered a wide range of current topics in drug metabolism research including predicting sites and routes of metabolism, metabolite identification, ligand docking, and medicinal and natural products chemistry, and highlighted approaches complemented by computational modeling. In silico tools have been increasingly applied in both academic and industrial settings, alongside traditional and evolving in vitro techniques, to strengthen and streamline pharmaceutical research. Approaches such as quantum mechanics simulations facilitate understanding of reaction energetics towards prediction of routes and sites of drug metabolism. Furthermore, in tandem with crystallographic and orthogonal wet lab techniques for structural validation of drug metabolizing enzymes, in silico models can aid understanding of substrate recognition by particular enzymes, identify metabolic soft spots and predict toxic metabolites for improved molecular design. Of note, integration of chemical synthesis and biosynthesis using natural products remains an important approach for identifying new chemical scaffolds in drug discovery. These subjects, compiled by the symposium organizers, presenters, and the ISSX New Investigators Group, are discussed in this review.

Published

2020

8. CYP2C9 and 3A4 play opposing roles in bioactivation and detoxification of diphenylamine NSAIDs

Author

Benjamin Mark Schleiff, Mary A. Schleiff, Grover P. Miller, Gunnar Boysen, Samantha Crosby, and Madison Blue

Subjects

Drug, media_common.quotation_subject, Pharmacology, digestive system, Biochemistry, Article, Substrate Specificity, chemistry.chemical_compound, Detoxification, Cytochrome P-450 CYP3A, Humans, CYP2C8, CYP2C9, media_common, Cytochrome P-450 CYP2C9, chemistry.chemical_classification, CYP3A4, Anti-Inflammatory Agents, Non-Steroidal, Diphenylamine, Metabolism, Enzyme, chemistry, Inactivation, Metabolic, Microsomes, Liver

Abstract

Diphenylamine NSAIDs are taken frequently for chronic pain conditions, yet their use may potentiate hepatotoxicity risks through poorly characterized metabolic mechanisms. Our previous work revealed that seven marketed or withdrawn diphenylamine NSAIDs undergo bioactivation into quinone-species metabolites, whose reaction specificities depended on halogenation and the type of acidic group on the diphenylamine. Herein, we identified cytochromes P450 responsible for those bioactivations, determined reaction specificities, and estimated relative contributions of enzymes to overall hepatic bioactivations and detoxifications. A qualitative activity screen revealed CYP2C8, 2C9, 2C19, and 3A4 played roles in drug bioactivation. Subsequent steady-state studies with recombinant CYPs recapitulated the importance of halogenation and acidic group type on bioactivations but importantly, showed patterns unique to each CYP. CYP2C9, 2C19 and 3A4 bioactivated all NSAIDs with CYP2C9 dominating all possible bioactivation pathways and their specificities. For each CYP, specificities for overall oxidative metabolism were not impacted significantly by differences in NSAID structures but the values themselves differed among the enzymes such that CYP2C9 and 3A4 were more efficient than others. When considering hepatic CYP abundance, CYP2C9 almost exclusively accounted for diphenylamine NSAID bioactivations, whereas CYP3A4 provided a critical counterbalance favoring their overall detoxification. Preference for either outcome would depend on molecular structures favoring metabolism by the CYPs as well as the influence of clinical factors altering their expression and/or activity. While focused on NSAIDs, these findings have broader implications on bioactivation risks given the expansion of the diphenylamine scaffold to other drug classes such as targeted cancer therapeutics.

Published

2021

9. 4-Methyl-1,2,3-Triazoles as N-Acetyl-Lysine Mimics Afford Potent BET Bromodomain Inhibitors with Improved Selectivity

Author

William C. K. Pomerantz, Huarui Cui, Nora R. Vail, Ke Shi, Anand Divakaran, Jorden A. Johnson, Huda Zahid, Grover P. Miller, Daniel A. Harki, Joseph J. Topczewski, Caroline R. Buchholz, Hideki Aihara, Mary A. Schleiff, and Angela S. Carlson

Subjects

BRD4, Protein family, Cell Survival, Lysine, Triazole, Cell Cycle Proteins, Article, chemistry.chemical_compound, Structure-Activity Relationship, Drug Discovery, Humans, Transcription factor, biology, Dose-Response Relationship, Drug, Molecular Structure, Triazoles, Bromodomain, Histone, chemistry, Biochemistry, Acetylation, A549 Cells, biology.protein, Microsomes, Liver, Molecular Medicine, Transcription Factors

Abstract

The bromodomain and extra terminal (BET) protein family recognizes acetylated lysines within histones and transcription factors using two N-terminal bromodomains, D1 and D2. The protein–protein interactions between BET bromodomains, acetylated histones, and transcription factors are therapeutic targets for BET-related diseases, including inflammatory disease and cancer. Prior work demonstrated that methylated-1,2,3-triazoles are suitable N-acetyl lysine mimetics for BET inhibition. Here we describe a structure–activity relationship study of triazole-based inhibitors that improve affinity, D1 selectivity, and microsomal stability. These outcomes were accomplished by targeting a nonconserved residue, Asp144 and a conserved residue, Met149, on BRD4 D1. The lead inhibitors DW34 and 26 have a BRD4 D1 K(d) of 12 and 6.4 nM, respectively. Cellular activity was demonstrated through suppression of c-Myc expression in MM.1S cells and downregulation of IL-8 in TNF-α-stimulated A549 cells. These data indicate that DW34 and 26 are new leads to investigate the anticancer and anti-inflammatory activity of BET proteins.

Published

2021

10. Recent developments in predicting CYP-independent metabolism

Author

Jasleen K. Sodhi, Bianka Haro, Khadjia A Lobo, Amit Kapadia, Mary A. Schleiff, Bernice Matusow, Christina Tantoy, and Nikhilesh V Dhuria

Subjects

Sulfotransferase, Monoamine oxidase, Metabolic Clearance Rate, Flavin-containing monooxygenase, urologic and male genital diseases, 030226 pharmacology & pharmacy, 03 medical and health sciences, chemistry.chemical_compound, Carboxylesterase, 0302 clinical medicine, Cytochrome P-450 Enzyme System, Humans, heterocyclic compounds, Pharmacology (medical), General Pharmacology, Toxicology and Pharmaceutics, Xanthine oxidase, Aldehyde oxidase, biology, Chemistry, organic chemicals, Cytochrome P450, respiratory system, enzymes and coenzymes (carbohydrates), Glutathione S-transferase, Biochemistry, 030220 oncology & carcinogenesis, Inactivation, Metabolic, biology.protein, Microsomes, Liver

Abstract

As lead optimization efforts have successfully reduced metabolic liabilities due to cytochrome P450 (CYP)-mediated metabolism, there has been an increase in the frequency of involvement of non-CYP enzymes in the metabolism of investigational compounds. Although there have been numerous notable advancements in the characterization of non-CYP enzymes with respect to their localization, reaction mechanisms, species differences and identification of typical substrates, accurate prediction of non-CYP-mediated clearance, with a particular emphasis with the difficulties in accounting for any extrahepatic contributions, remains a challenge. The current manuscript comprehensively summarizes the recent advancements in the prediction of drug metabolism and the

Published

2021

11. Novel Bioactivation of Isoxazole‐containing Bromodomain and Extra Terminal Domain (BET) Inhibitors

Author

S.J. Swamidass, Michael D. Ward, Mary A. Schleiff, Noah R. Flynn, Stuart J. Conway, Coretine Laurin, and Grover P. Miller

Subjects

chemistry.chemical_compound, Terminal (electronics), Chemistry, Stereochemistry, Genetics, Isoxazole, Molecular Biology, Biochemistry, Biotechnology, Bromodomain, Domain (software engineering)

Published

2021

12. International Society for the Study of Xenobiotics (ISSX) New Investigator Group Committee 2019-2020 concluding remarks

Author

Mary A. Schleiff and Jasleen K. Sodhi

Subjects

Teamwork, Medical education, media_common.quotation_subject, 030226 pharmacology & pharmacy, Xenobiotics, 03 medical and health sciences, 0302 clinical medicine, Group (periodic table), 030220 oncology & carcinogenesis, Humans, Pharmacology (medical), General Pharmacology, Toxicology and Pharmaceutics, Psychology, media_common

Abstract

The International Society for the Study of Xenobiotics (ISSX) New Investigators Group has assembled a global team of emerging scientists to collaboratively compose a series of articles whose topics span the broad field of drug metabolism and will guide both new and established investigators alike. The New Investigator Group Committee members are proud to have provided such an opportunity to many promising early-career scientists from across the globe, and would like to acknowledge each contributor for their efforts.

Published

2021

13. Significance of Competing Metabolic Pathways for 5F-APINACA Based on Quantitative Kinetics

Author

Dakota L. Pouncey, Anna Radominska-Pandya, Anna O. Pinson, Grover P. Miller, Gunnar Boysen, Mary A. Schleiff, Paul L. Prather, and William E. Fantegrossi

Subjects

CB1 receptor, Indazoles, Metabolite, Kinetics, Pharmaceutical Science, Adamantane, 030226 pharmacology & pharmacy, 5F-AKB48, Article, Analytical Chemistry, Absorbance, lcsh:QD241-441, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, lcsh:Organic chemistry, Drug Discovery, Synthetic cannabinoids, medicine, Humans, Physical and Theoretical Chemistry, drug abuse, Chemistry, Cannabinoids, 5F-APINACA, Organic Chemistry, Metabolism, Metabolic pathway, Biochemistry, Chemistry (miscellaneous), Dihydroxylation, Microsomes, Liver, Molecular Medicine, synthetic cannabinoid, Flux (metabolism), 030217 neurology & neurosurgery, Metabolic Networks and Pathways, medicine.drug, P450

Abstract

In 2020, nearly one-third of new drugs on the global market were synthetic cannabinoids including the drug of abuse N-(1-adamantyl)-1-(5-pentyl)-1H-indazole-3-carboxamide (5F-APINACA, 5F-AKB48). Knowledge of 5F-APINACA metabolism provides a critical mechanistic basis to interpret and predict abuser outcomes. Prior qualitative studies identified which metabolic processes occur but not the order and extent of them and often relied on problematic &ldquo, semi-quantitative&rdquo, mass spectroscopic (MS) approaches. We capitalized on 5F-APINACA absorbance for quantitation while leveraging MS to characterize metabolite structures for measuring 5F-APINACA steady-state kinetics. We demonstrated the reliability of absorbance and not MS for inferring metabolite levels. Human liver microsomal reactions yielded eight metabolites by MS but only five by absorbance. Subsequent kinetic studies on primary and secondary metabolites revealed highly efficient mono- and dihydroxylation of the adamantyl group and much less efficient oxidative defluorination at the N-pentyl terminus. Based on regiospecificity and kinetics, we constructed pathways for competing and intersecting steps in 5F-APINACA metabolism. Overall efficiency for adamantyl oxidation was 17-fold higher than that for oxidative defluorination, showing significant bias in metabolic flux and subsequent metabolite profile compositions. Lastly, our analytical approach provides a powerful new strategy to more accurately assess metabolic kinetics for other understudied synthetic cannabinoids possessing the indazole chromophore.

Published

2020

14. Meloxicam methyl group determines enzyme specificity for thiazole bioactivation compared to sudoxicam

Author

Dustyn A. Barnette, Grover P. Miller, S. Joshua Swamidass, Mary A. Schleiff, Arghya Datta, and Noah R. Flynn

Subjects

0301 basic medicine, Male, Thiazines, Pharmacology, Toxicology, Meloxicam, Isozyme, Article, Substrate Specificity, Activation, Metabolic, Cytochrome P-450 CYP2C8, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Deep Learning, Cytochrome P-450 CYP1A2, medicine, Data Mining, Electronic Health Records, Humans, Drug Interactions, Thiazole, CYP2C8, CYP2C9, Cytochrome P-450 CYP2C9, chemistry.chemical_classification, biology, Chemistry, Anti-Inflammatory Agents, Non-Steroidal, CYP1A2, Cytochrome P450, General Medicine, Middle Aged, Kinetics, 030104 developmental biology, Enzyme, Inactivation, Metabolic, biology.protein, Microsomes, Liver, Female, Chemical and Drug Induced Liver Injury, 030217 neurology & neurosurgery, medicine.drug

Abstract

Meloxicam is a thiazole-containing NSAID that was approved for marketing with favorable clinical outcomes despite being structurally similar to the hepatotoxic sudoxicam. Introduction of a single methyl group on the thiazole results in an overall lower toxic risk, yet the group’s impact on P450 isozyme bioactivation is unclear. Through analytical methods, we used inhibitor phenotyping and recombinant P450s to identify contributing P450s, and then measured steady-state kinetics for bioactivation of sudoxicam and meloxicam by the recombinant P450s to determine relative efficiencies. Experiments showed that CYP2C8, 2C19, and 3A4 catalyze sudoxicam bioactivation, and CYP1A2 catalyzes meloxicam bioactivation, indicating that the methyl group not only impacts enzyme affinity for the drugs, but also alters which isozymes catalyze the metabolic pathways. Scaling of relative P450 efficiencies based on average liver concentration revealed that CYP2C8 dominates the sudoxicam bioactivation pathway and CYP2C9 dominates meloxicam detoxification. Dominant P450s were applied for an informatics assessment of electronic health records to identify potential correlations between meloxicam drug-drug interactions and drug-induced liver injury. Overall, our findings provide a cautionary tale on assumed impacts of even simple structural modifications on drug bioactivation while also revealing specific targets for clinical investigations of predictive factors that determine meloxicam-induced idiosyncratic liver injury.

Published

2020

15. Bioactivation of Isoxazole-Containing Bromodomain and Extra-Terminal Domain (BET) Inhibitors

Author

Rohit Farmer, Stuart J. Conway, Mary A. Schleiff, Grover P. Miller, S. Joshua Swamidass, Corentine M.C. Laurin, Michael D. Ward, Gunnar Boysen, and Noah R. Flynn

Subjects

quinone, 0301 basic medicine, reactive metabolite, Endocrinology, Diabetes and Metabolism, Metabolite, Microbiology, 01 natural sciences, Biochemistry, Article, BET inhibitor, 03 medical and health sciences, chemistry.chemical_compound, bromodomain, Molecule, Reactivity (chemistry), glutathione, Isoxazole, Molecular Biology, chemistry.chemical_classification, model, bioactivation, pathway, 010405 organic chemistry, Chemistry, Biomolecule, isoxazole, deep neural network, Combinatorial chemistry, QR1-502, 0104 chemical sciences, Quinone, Bromodomain, inhibitor, 030104 developmental biology

Abstract

The 3,5-dimethylisoxazole motif has become a useful and popular acetyl-lysine mimic employed in isoxazole-containing bromodomain and extra-terminal (BET) inhibitors but may introduce the potential for bioactivations into toxic reactive metabolites. As a test, we coupled deep neural models for quinone formation, metabolite structures, and biomolecule reactivity to predict bioactivation pathways for 32 BET inhibitors and validate the bioactivation of select inhibitors experimentally. Based on model predictions, inhibitors were more likely to undergo bioactivation than reported non-bioactivated molecules containing isoxazoles. The model outputs varied with substituents indicating the ability to scale their impact on bioactivation. We selected OXFBD02, OXFBD04, and I-BET151 for more in-depth analysis. OXFBD’s bioactivations were evenly split between traditional quinones and novel extended quinone-methides involving the isoxazole yet strongly favored the latter quinones. Subsequent experimental studies confirmed the formation of both types of quinones for OXFBD molecules, yet traditional quinones were the dominant reactive metabolites. Modeled I-BET151 bioactivations led to extended quinone-methides, which were not verified experimentally. The differences in observed and predicted bioactivations reflected the need to improve overall bioactivation scaling. Nevertheless, our coupled modeling approach predicted BET inhibitor bioactivations including novel extended quinone methides, and we experimentally verified those pathways highlighting potential concerns for toxicity in the development of these new drug leads.

Published

2021

16. Dual mechanisms suppress meloxicam bioactivation relative to sudoxicam

Author

Noah R. Flynn, Grover P. Miller, Laura R. Osborn, Mary A. Schleiff, Dustyn A. Barnette, Matthew K. Matlock, and S. Joshua Swamidass

Subjects

0301 basic medicine, Stereochemistry, Thiazines, Electrons, In Vitro Techniques, Hydroxylation, Meloxicam, Toxicology, Article, Activation, Metabolic, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Detoxification, medicine, Humans, Thiazole, Biotransformation, Biological activity, Kinetics, Thiazoles, Metabolic pathway, 030104 developmental biology, chemistry, Microsomes, Liver, Microsome, Epoxy Compounds, Chemical and Drug Induced Liver Injury, Metabolic Networks and Pathways, 030217 neurology & neurosurgery, medicine.drug, Methyl group

Abstract

Thiazoles are biologically active aromatic heterocyclic rings occurring frequently in natural products and drugs. These molecules undergo typically harmless elimination; however, a hepatotoxic response can occur due to multistep bioactivation of the thiazole to generate a reactive thioamide. A basis for those differences in outcomes remains unknown. A textbook example is the high hepatotoxicity observed for sudoxicam in contrast to the relative safe use and marketability of meloxicam, which differs in structure from sudoxicam by the addition of a single methyl group. Both drugs undergo bioactivation, but meloxicam exhibits an additional detoxification pathway due to hydroxylation of the methyl group. We hypothesized that thiazole bioactivation efficiency is similar between sudoxicam and meloxicam due to the methyl group being a weak electron donator, and thus, the relevance of bioactivation depends on the competing detoxification pathway. For a rapid analysis, we modeled epoxidation of sudoxicam derivatives to investigate the impact of substituents on thiazole bioactivation. As expected, electron donating groups increased the likelihood for epoxidation with a minimal effect for the methyl group, but model predictions did not extrapolate well among all types of substituents. Through analytical methods, we measured steady-state kinetics for metabolic bioactivation of sudoxicam and meloxicam by human liver microsomes. Sudoxicam bioactivation was 6-fold more efficient than that for meloxicam, yet meloxicam showed a 6-fold higher efficiency of detoxification than bioactivation. Overall, sudoxicam bioactivation was 15-fold more likely than meloxicam considering all metabolic clearance pathways. Kinetic differences likely arise from different enzymes catalyzing respective metabolic pathways based on phenotyping studies. Rather than simply providing an alternative detoxification pathway, the meloxicam methyl group suppressed the bioactivation reaction. These findings indicate the impact of thiazole substituents on bioactivation is more complex than previously thought and likely contributes to the unpredictability of their toxic potential.

Published

2020