Abstract
The Cre/lox system is a potent technology to control gene expression in mouse tissues. However, cardiac-specific Cre recombinase expression alone can lead to cardiac alterations when no loxP sites are present, which is not well understood. Many loxP-like sites have been identified in the mouse genome that might be Cre sensitive. One of them is located in the Dmd gene encoding dystrophin, a protein important for the function and stabilization of voltage-gated calcium (Cav1.2) and sodium (Nav1.5) channels, respectively. Here, we investigate whether Cre affects dystrophin expression and function in hearts without loxP sites in the genome. In mice expressing Cre under the alpha-myosin heavy chain (MHC-Cre) or Troponin T (TNT-Cre) promoter, we investigated dystrophin expression, Nav1.5 expression, and Cav1.2 function. Compared to age-matched MHC-Cre− mice, dystrophin protein level was significantly decreased in hearts from MHC-Cre+ mice of more than 12-weeks-old. Quantitative RT-PCR revealed decreased mRNA levels of Dmd gene. Unexpectedly, calcium current (ICaL), but not Nav1.5 protein expression was altered in those mice. Surprisingly, in hearts from 12-week-old and older TNT-Cre+ mice, neither ICaL nor dystrophin and Nav1.5 protein content were altered compared to TNT-Cre−. Cre recombinase unpredictably affects cardiac phenotype, and Cre-expressing mouse models should be carefully investigated before experimental use.
Highlights
IntroductionDifferent genome manipulation technologies have been developed to investigate the function of specific genes in vivo
Over the past decades, different genome manipulation technologies have been developed to investigate the function of specific genes in vivo
Our present work strongly suggests that the myosin-heavy chain (MHC)-Cre model should be carefully characterized before using it for any experiment, mainly because Cre expression reduces dystrophin protein and mRNA expression
Summary
Different genome manipulation technologies have been developed to investigate the function of specific genes in vivo. One potential mechanism to explain the side effects of Cre expression is the presence of loxP-like sites in the wild-type genome that are sensitive to Cre activity[3,4] One of these loxP-like site is localized in the Dmd gene that encodes the structural protein dystrophin[3]. The absence of dystrophin in dystrophinopathies such as Duchene muscular dystrophy alters the current mediated by the voltage-gated calcium channel Cav1.2 (ICaL) and the whole-cell protein content of voltage-gated sodium channel Nav1.56–9 Based on these observations and knowing that Cav1.2 and Nav1.5 are pivotal players in cardiac function, we compared dystrophin protein expression, ICaL, and whole-cell Nav1.5 protein expression in hearts between MHC-Cre−, MHC-Cre+, TNT-Cre−, and TNT-Cre+ mice
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