Generating endogenous Myh11-driven Cre mice for sex-independent gene deletion in smooth muscle cells
Yang Zhao, … , Y. Eugene Chen, Jifeng Zhang
Yang Zhao, … , Y. Eugene Chen, Jifeng Zhang
Published June 8, 2023
Citation Information: JCI Insight. 2023;8(14):e171661. https://doi.org/10.1172/jci.insight.171661.
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Resource and Technical Advance Angiogenesis Vascular biology

Generating endogenous Myh11-driven Cre mice for sex-independent gene deletion in smooth muscle cells

Abstract

Specific and efficient smooth muscle cell–targeted (SMC-targeted) gene deletion is typically achieved by pairing SMMHC-CreERT2-Tg mice with mice carrying the loxP-flanked gene. However, the transgene, CreERT2, is not controlled by the endogenous Myh11 gene promoter, and the codon-modified iCreERT2 exhibits significant tamoxifen-independent leakage. Furthermore, because the Cre-bearing bacterial artificial chromosome (BAC) is inserted onto the Y chromosome, the SMMHC-CreERT2-Tg mice strain can only exhibit gene deletions in male mice. Additionally, there is a lack of Myh11-driven constitutive Cre mice when tamoxifen usage is a concern. We used CRISPR/Cas9-mediated homologous recombination between a donor vector carrying the CreNLSP2A or CreERT2–P2A sequence and homologous arm surrounding the translation start site of the Myh11 gene to generate Cre-knockin mice. The P2A sequence enables the simultaneous translation of Cre and endogenous proteins. Using reporter mice, we assessed Cre-mediated recombination efficiency, specificity, tamoxifen-dependent controllability, and functionality in both sexes. Both constitutive (Myh11-CreNLSP2A) and inducible (Myh11-CreERT2–P2A) Cre mice demonstrated efficient, SMC-specific, sex-independent Cre recombinase activity without confounding endogenous gene expression. Combined with recently generated BAC transgenic Myh11-CreERT2-RAD mice and the Itga8-CreERT2 mouse models, our models will help expand the research toolbox, facilitating unbiased and comprehensive research in SMCs and SMC-dependent cardiovascular diseases.

Authors

Yang Zhao, Guizhen Zhao, Ziyi Chang, Tianqing Zhu, Ying Zhao, Haocheng Lu, Chao Xue, Thomas L. Saunders, Yanhong Guo, Lin Chang, Y. Eugene Chen, Jifeng Zhang

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Figure 1

Generation and characterization of Myh11-CreNLSP2A KI mice.

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Generation and characterization of Myh11-CreNLSP2A KI mice. (A) Schemati...
(A) Schematic illustration of the strategy for generating endogenous Myh11-driven smooth muscle–targeted Myh11-CreNLSP2A KI mice. (B) PCR confirmation of the Myh11-CreNLSP2A KI insertion site for F0 founder mice and identification of Myh11-CreNLSP2A–/–, Myh11-CreNLSP2A+/–, and Myh11-CreNLSP2A+/+ offspring. (CF) Effect of Myh11-CreNLSP2A KI on offspring Mendelian distribution (C), systolic blood pressure (D), endogenous Myh11 gene expression in the aorta, bladder, jejunum, and stomach (E) (n = 6–10 per group), and Western blot quantification of Myosin-11 (F) (coded by Myh11) protein abundance in the aorta (n = 4 per group). (G) Myh11-CreNLSP2A KI mice were crossbred with ROSA26-driven mT/mG reporter mice. Cre activity in the aorta is proportional to the loss of tdTomato (red) signal and gain of EGFP (green) signal. Scale bars: 50 μm (upper left); 100 μm (lower right). L, aortic lumen. (H) Myh11-CreNLSP2A KI mice were crossbred with BAF60a-floxed mice, followed by quantification of KO efficiency in the aorta and bladder using qPCR (n = 3 per group). Data are presented as mean ± SEM. Unpaired, 2-tailed Student’s t test (F and H), 1-way ANOVA (D), and 2-way ANOVA (E) followed by the Tukey test were used.