Your search keyword '"Lorenzini, Maxime"' showing total 5 results

1. Determinants of iFGF13-mediated regulation of myocardial voltage-gated sodium (NaV) channels in mouse

Author

Lesage, Adrien, primary, Lorenzini, Maxime, additional, Burel, Sophie, additional, Sarlandie, Marine, additional, Bibault, Floriane, additional, Lindskog, Cecilia, additional, Maloney, Daniel, additional, Silva, Jonathan R., additional, Townsend, R. Reid, additional, Nerbonne, Jeanne M., additional, and Marionneau, Céline, additional

Published

2023

2. Determinants of iFGF13-mediated regulation of myocardial voltage-gated sodium (NaV) channels in mouse

Author

Lesage, Adrien, Lorenzini, Maxime, Burel, Sophie, Sarlandie, Marine, Bibault, Floriane, Lindskog, Cecilia, Maloney, Daniel, Silva, Jonathan R., Townsend, R. Reid, Nerbonne, Jeanne M., Marionneau, Celine, Lesage, Adrien, Lorenzini, Maxime, Burel, Sophie, Sarlandie, Marine, Bibault, Floriane, Lindskog, Cecilia, Maloney, Daniel, Silva, Jonathan R., Townsend, R. Reid, Nerbonne, Jeanne M., and Marionneau, Celine

Abstract

Posttranslational regulation of cardiac Na(V)1.5 channels is critical in modulating channel expression and function, yet their regulation by phosphorylation of accessory proteins has gone largely unexplored. Using phosphoproteomic analysis of Na-V channel complexes from adult mouse left ventricles, we identified nine phosphorylation sites on intracellular fibroblast growth factor 13 (iFGF13). To explore the potential roles of these phosphosites in regulating cardiac NaV currents, we abolished expression of iFGF13 in neonatal and adult mouse ventricular myocytes and rescued it with wild-type (WT), phosphosilent, or phosphomimetic iFGF13-VY. While the increased rate of closed-state inactivation of NaV channels induced by Fgf13 knockout in adult cardiomyocytes was completely restored by adenoviral-mediated expression of WT iFGF13-VY, only partial rescue was observed in neonatal cardiomyocytes after knockdown. The knockdown of iFGF13 in neonatal ventricular myocytes also shifted the voltage dependence of channel activation toward hyperpolarized potentials, a shift that was not reversed by WT iFGF13-VY expression. Additionally, we found that iFGF13-VY is the predominant isoform in adult ventricular myocytes, whereas both iFGF13-VY and iFGF13-S are expressed comparably in neonatal ventricular myocytes. Similar to WT iFGF13-VY, each of the iFGF13-VY phosphomutants studied restored NaV channel inactivation properties in both models. Lastly, Fgf13 knockout also increased the late Na+ current in adult cardiomyocytes, and this effect was restored with expression of WT and phosphosilent iFGF13-VY. Together, our results demonstrate that iFGF13 is highly phosphorylated and displays differential isoform expression in neonatal and adult ventricular myocytes. While we found no roles for iFGF13 phosphorylation, our results demonstrate differential effects of iFGF13 on neonatal and adult mouse ventricular NaV channels.

Published

2023

3. FHF2 phosphorylation and regulation of native myocardial NaV1.5 channels

Author

Lesage, Adrien, primary, Lorenzini, Maxime, additional, Burel, Sophie, additional, Sarlandie, Marine, additional, Bibault, Floriane, additional, Maloney, Dan, additional, Silva, Jonathan R., additional, Reid Townsend, R., additional, Nerbonne, Jeanne M., additional, and Marionneau, Céline, additional

Published

2023

4. Rapamycin treatment unmasks a sex‐specific pattern of scar expansion of the infarcted rat heart: The relationship between mTOR and KATP channel.

Author

Al‐Katat, Aya, Bergeron, Alexandre, Parent, Lucie, Lorenzini, Maxime, Fiset, Celine, and Calderone, Angelino

Subjects

RAPAMYCIN, HYPERTROPHIC scars, RATS, HEART, SCARS

Abstract

Inhibition of the mammalian target of rapamycin (mTOR) with the macrolide rapamycin or pharmacological suppression of KATP channel opening translated to scar expansion of the myocardial infarcted (MI) adult female rodent heart. The present study tested the hypotheses that rapamycin‐mediated scar expansion was sex‐specific and that mTOR signaling directly influenced KATP channel subunit expression/activity. Scar size was significantly larger in post‐MI male rats as compared to the previous data reported in post‐MI female rats. The reported scar expansion of rapamycin‐treated post‐MI female rats was not observed following the administration of the macrolide to post‐MI male rats. Protein levels of the KATP channel subunits Kir6.2 and SUR2A and phosphorylation of the serine2448 residue of mTOR were similar in the normal heart of adult male and female rats. By contrast, greater tuberin inactivation characterized by the increased phosphorylation of the threonine1462 residue and reduced raptor protein levels were identified in the normal heart of adult female rats. Rapamycin pretreatment of phorbol 12,13‐dibutyrate (PDBu)‐treated neonatal rat ventricular cardiomyocytes (NNVMs) suppressed hypertrophy, inhibited p70S6K phosphorylation, and attenuated SUR2A protein upregulation. In the presence of low ATP levels, KATP channel activity detected in untreated NNVMs was significantly attenuated in PDBu‐induced hypertrophied NNVMs via a rapamycin‐independent pathway. Thus, rapamycin administration to post‐MI rats unmasked a sex‐specific pattern of scar expansion and mTOR signaling in PDBu‐induced hypertrophied NNVMs significantly increased SUR2A protein levels. However, the biological advantage associated with SUR2A protein upregulation was partially offset by an mTOR‐independent pathway that attenuated KATP channel activity in PDBu‐induced hypertrophied NNVMs. [ABSTRACT FROM AUTHOR]

Published

2023

5. FHF2 phosphorylation and regulation of native myocardial Na V 1.5 channels.

Author

Lesage A, Lorenzini M, Burel S, Sarlandie M, Bibault F, Maloney D, Silva JR, Reid Townsend R, Nerbonne JM, and Marionneau C

Abstract

Phosphorylation of the cardiac Na V 1.5 channel pore-forming subunit is extensive and critical in modulating channel expression and function, yet the regulation of Na V 1.5 by phosphorylation of its accessory proteins remains elusive. Using a phosphoproteomic analysis of Na V channel complexes purified from mouse left ventricles, we identified nine phosphorylation sites on Fibroblast growth factor Homologous Factor 2 (FHF2). To determine the roles of phosphosites in regulating Na V 1.5, we developed two models from neonatal and adult mouse ventricular cardiomyocytes in which FHF2 expression is knockdown and rescued by WT, phosphosilent or phosphomimetic FHF2-VY. While the increased rates of closed-state and open-state inactivation of Na V channels induced by the FHF2 knockdown are completely restored by the FHF2-VY isoform in adult cardiomyocytes, sole a partial rescue is obtained in neonatal cardiomyocytes. The FHF2 knockdown also shifts the voltage-dependence of activation towards hyperpolarized potentials in neonatal cardiomyocytes, which is not rescued by FHF2-VY. Parallel investigations showed that the FHF2-VY isoform is predominant in adult cardiomyocytes, while expression of FHF2-VY and FHF2-A is comparable in neonatal cardiomyocytes. Similar to WT FHF2-VY, however, each FHF2-VY phosphomutant restores the Na V channel inactivation properties in both models, preventing identification of FHF2 phosphosite roles. FHF2 knockdown also increases the late Na + current in adult cardiomyocytes, which is restored similarly by WT and phosphosilent FHF2-VY. Together, our results demonstrate that ventricular FHF2 is highly phosphorylated, implicate differential roles for FHF2 in regulating neonatal and adult mouse ventricular Na V 1.5, and suggest that the regulation of Na V 1.5 by FHF2 phosphorylation is highly complex., Etoc Summary: Lesage et al . identify the phosphorylation sites of FHF2 from mouse left ventricular Na V 1.5 channel complexes. While no roles for FHF2 phosphosites could be recognized yet, the findings demonstrate differential FHF2-dependent regulation of neonatal and adult mouse ventricular Na V 1.5 channels.

Published

2023