Gaia Papini scite author profile

The adult myocardium has limited capacity to preserve, renew or rejuvenate itself. The local microenvironment may induce epigenetic changes affecting the survival, proliferation, function and senescence of cardiac cells at rest and following the exposure to different stressors. The cellular response to microenvironment is characterized by the release of ions, oxygen free radicals, auto/paracrine factors and RNAs that drive the magnitude of gene reprogramming through the interaction with specific promoters. The epigenetic alterations may act at transcriptional and post-transcriptional level and change cardiac physiological traits. The abnormal DNA methylation underlies the progressive decay of contractile function and the angiogenic ability; while, the histone acetylation promotes the survival, function and proliferation of cardiac cells in the presence of ischemic microenvironment. At least, the expression and secretion of microRNAs and long noncoding RNAs may regulate the threshold to stress tolerance of adult cardiac cells and induce the matrix turnover as well. Natural or synthetic active compounds effectively modulate the epigenetic state of cardiac cells. Plant foods contain many active compounds with epigenetic properties and might assume a clinical significance as natural cardiac regenerators or rejuvenators. Our review describes novel epigenetic mechanisms that underpin myocardial remodeling, repair/ regeneration or senescence in order to support the development of most effective and reproducible rescue therapy of adult heart.

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Cardiomyocyte-targeting exosomes from sulforaphane-treated fibroblasts affords cardioprotection in infarcted rats

Papini

Furini

Matteucci

et al. 2023

J Transl Med

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Background Exosomes (EXOs), tiny extracellular vesicles that facilitate cell–cell communication, are being explored as a heart failure treatment, although the features of the cell source restrict their efficacy. Fibroblasts the most prevalent non-myocyte heart cells, release poor cardioprotective EXOs. A noninvasive method for manufacturing fibroblast-derived exosomes (F-EXOs) that target cardiomyocytes and slow cardiac remodeling is expected. As a cardioprotective isothiocyanate, sulforaphane (SFN)-induced F-EXOs (SFN-F-EXOs) should recapitulate its anti-remodeling properties. Methods Exosomes from low-dose SFN (3 μM/7 days)-treated NIH/3T3 murine cells were examined for number, size, and protein composition. Fluorescence microscopy, RT-qPCR, and western blot assessed cell size, oxidative stress, AcH4 levels, hypertrophic gene expression, and caspase-3 activation in angiotensin II (AngII)-stressed HL-1 murine cardiomyocytes 12 h-treated with various EXOs. The uptake of fluorescently-labeled EXOs was also measured in cardiomyocytes. The cardiac function of infarcted male Wistar rats intramyocardially injected with different EXOs (1·1012) was examined by echocardiography. Left ventricular infarct size, hypertrophy, and capillary density were measured. Results Sustained treatment of NIH/3T3 with non-toxic SFN concentration significantly enhances the release of CD81 + EXOs rich in TSG101 (Tumor susceptibility gene 101) and Hsp70 (Heat Shock Protein 70), and containing maspin, an endogenous histone deacetylase 1 inhibitor. SFN-F-EXOs counteract angiotensin II (AngII)-induced hypertrophy and apoptosis in murine HL-1 cardiomyocytes enhancing SERCA2a (sarcoplasmic/endoplasmic reticulum Ca2+ ATPase 2a) levels more effectively than F-EXOs. In stressed cardiomyocytes, SFN-F-EXOs boost AcH4 levels by 30% (p < 0.05) and significantly reduce oxidative stress more than F-EXOs. Fluorescence microscopy showed that mouse cardiomyocytes take in SFN-F-EXOs ~ threefold more than F-EXOs. Compared to vehicle-injected infarcted hearts, SFN-F-EXOs reduce hypertrophy, scar size, and improve contractility. Conclusions Long-term low-dose SFN treatment of fibroblasts enhances the release of anti-remodeling cardiomyocyte-targeted F-EXOs, which effectively prevent the onset of HF. The proposed method opens a new avenue for large-scale production of cardioprotective exosomes for clinical application using allogeneic fibroblasts.

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Regulation of the Adaptive Response of Cardiac Cells to Ischemia: Role of Nanovesicles

Papini¹,

Lionetti²

2017

NanoWorld J

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Ischemic heart disease represents 1 in 4 of total global deaths worldwide. Myocardial intercellular cross-talk regulate simultaneously the tissue homeostasis between neighboring cardiac cells in response to acute or chronic ischemic insult. Different studies have suggested that the heterocellular communication of adult myocardium is mainly based on the release of several free soluble biofactors into the extracellular milieu and on the spreading of different ions through selective channels. In light of these findings, the past few decades have witnessed incessant research aimed at protecting the adult myocardium against ischemic injury, but the development of effective cardioprotection is still a desirable achievement. Nowadays, the rapidly evolving nanoscience is offering the opportunity to tailor new reliable therapeutic targets at ultrastructural level in order to prevent or attenuate the progressive myocardial trimodal response (cell death, matrix degradation and reactive cell hypertrophy) against ischemic injury occurring in infarcted heart. All cardiac cell types release nanovesicles termed "exosomes" (size 40-100 nm), which contain different cargo under normoxic and hypoxic microenvironment. In particular, we and other investigators have demostrated that cardiac fibroblasts and cardiac progenitor cells/stem cells interact with ischemic cardiomyocytes through the release of exosomes. Our review provides current insights into the role of nanovesicles in the modulation of injury and repair responses under ischemic microenvironment.

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Epigenetic Regulation of Cardiac Regeneration

Agostini

Matteucci

Casieri

et al. 2015

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Gaia Papini

Plasma exosomes characterization reveals a perioperative protein signature in older patients undergoing different types of on-pump cardiac surgery

Epigenetic Regulation of Myocardial Homeostasis, Self-Regeneration and Senescence

Cardiomyocyte-targeting exosomes from sulforaphane-treated fibroblasts affords cardioprotection in infarcted rats

Regulation of the Adaptive Response of Cardiac Cells to Ischemia: Role of Nanovesicles

Epigenetic Regulation of Cardiac Regeneration

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