Toxicokinetic Interaction between Hepatic Disposition and Pulmonary Bioactivation of Inhaled Naphthalene Studied Using <i>Cyp2abfgs</i>-Null and CYP2A13/2F1-Humanized Mice with Deficient Hepatic Cytochrome P450 Activity

Kovalchuk, Nataliia; Kelty, Jacklyn Skye; Winkle, Laura S. Van; Ding, Xinxin

doi:10.1124/dmd.119.088930

Cited by 8 publications

(1 citation statement)

References 31 publications

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“…Published on October 23, 2022as DOI: 10.1124 at ASPET Journals on November 6, 2022 dmd.aspetjournals.org Downloaded from with CYP2A13 and CYP2F1 produced in the lung and nasal mucosa, and CYP2B6 produced in the liver (Wei et al, 2012). The CYP2A13/2B6/2F1-transgenic mouse model has been utilized in several published studies, e.g., to demonstrate the role of CYP2A13 in NNK-induced lung tumorigenesis (Megaraj et al, 2014), the role of CYP2A13 and CYP2F1 in naphthalene-induced lung toxicity (Li et al, 2017;Kovalchuk et al, 2019), the regulation of CYP2A13 by inflammation and lung tumorigenesis (Wu et al, 2013;Liu et al, 2015b), and the role of hepatic CYP2B6 in nicotine metabolism in vivo (Liu et al, 2015a). The mouse model is also utilized in a number of ongoing studies by several laboratories.…”

Section: Introductionmentioning

confidence: 99%

Detection of Transgene Location in the CYP2A13/2B6/2F1-transgenic Mouse Model using Optical Genome Mapping Technology

2022

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Most transgenic mouse models are generated through random integration of the transgene.The location of the transgene provides valuable information for assessing potential effects of the transgenesis on the host and for designing genotyping protocols that can amplify across the integration site, but it is challenging to identify. Here, we report the successful utility of optical genome mapping technology to identify the transgene insertion site in a CYP2A13/2B6/2F1transgenic mouse model, which produces three human cytochrome P450 enzymes (CYP2A13, CYP2B6, and CYP2F1) that are encoded by neighboring genes on human chromosome 19.These enzymes metabolize many drugs, respiratory toxicants, and chemical carcinogens. Initial efforts to identify candidate insertion sites by whole genome sequencing was unsuccessful, apparently because the transgene is located in a region of the mouse genome that contains highly repetitive sequences. Subsequent utility of the optical genome mapping approach, which compares genome-wide marker distribution between the transgenic mouse genome and a reference mouse (GRCm38) or human (GRCh38) genome, localized the insertion site to mouse chromosome 14, between two marker positions at 4451324 base pair and 4485032 base pair. A transgene-mouse genome junction sequence was further identified through long-PCR amplification and DNA sequencing at GRCm38 Chr.14:4484726. The transgene insertion (~2.4 megabase pair) contained 5-7 copies of the human transgenes, which replaced a 26.9-33.4 kilobase-pair mouse genomic region, including exons 1-4 of Gm3182, a predicted and highly redundant gene. Finally, the sequencing results enabled the design of a new genotyping protocol that can distinguish between hemizygous and homozygous CYP2A13/2B6/2F1-transgenic mice.

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