Your search keyword '"Ceriotti, Paola"' showing total 7 results

1. Peptide-Based Targeting of the L-Type Calcium Channel Corrects the Loss-of-Function Phenotype of Two Novel Mutations of the CACNA1 Gene Associated With Brugada Syndrome.

Author

Di Mauro, Vittoria, Ceriotti, Paola, Lodola, Francesco, Salvarani, Nicolò, Modica, Jessica, Bang, Marie-Louise, Mazzanti, Andrea, Napolitano, Carlo, Priori, Silvia G., and Catalucci, Daniele

Subjects

CALCIUM channels, PHENOTYPES, GENETIC mutation, CELL membranes, HEART cells, BRUGADA syndrome

Abstract

Brugada syndrome (BrS) is an inherited arrhythmogenic disease that may lead to sudden cardiac death in young adults with structurally normal hearts. No pharmacological therapy is available for BrS patients. This situation highlights the urgent need to overcome current difficulties by developing novel groundbreaking curative strategies. BrS has been associated with mutations in 18 different genes of which loss-of-function (LoF) CACNA1C mutations constitute the second most common cause. Here we tested the hypothesis that BrS associated with mutations in the CACNA1C gene encoding the L-type calcium channel (LTCC) pore-forming unit (Cavα1.2) is functionally reverted by administration of a mimetic peptide (MP), which through binding to the LTCC chaperone beta subunit (Cavβ2) restores the physiological life cycle of aberrant LTCCs. Two novel Cavα1.2 mutations associated with BrS were identified in young individuals. Transient transfection in heterologous and cardiac cells showed LoF phenotypes with reduced Ca2+ current (ICa). In HEK293 cells overexpressing the two novel Cavα1.2 mutations, Western blot analysis and cell surface biotinylation assays revealed reduced Cavα1.2 protein levels at the plasma membrane for both mutants. Nano-BRET, Nano-Luciferase assays, and confocal microscopy analyses showed (i) reduced affinity of Cavα1.2 for its Cavβ2 chaperone, (ii) shortened Cavα1.2 half-life in the membrane, and (iii) impaired subcellular localization. Treatment of Cavα1.2 mutant-transfected cells with a cell permeant MP restored channel trafficking and physiologic channel half-life, thereby resulting in ICa similar to wild type. These results represent the first step towards the development of a gene-specific treatment for BrS due to defective trafficking of mutant LTCC. [ABSTRACT FROM AUTHOR]

Published

2021

2. High Intensity Interval Training Ameliorates Mitochondrial Dysfunction in the Left Ventricle of Mice with Type 2 Diabetes.

Author

Bækkerud, Fredrik H., Salerno, Simona, Ceriotti, Paola, Morland, Cecilie, Storm-Mathisen, Jon, Bergersen, Linda H., Høydal, Morten A., Catalucci, Daniele, and Stølen, Tomas O.

Subjects

INTERVAL training, TYPE 2 diabetes, GLYCEMIC index, STRENGTH training, SUCCINATE dehydrogenase, HIGH-intensity interval training, OXIDATIVE phosphorylation

Abstract

Both human and animal studies have shown mitochondrial and contractile dysfunction in hearts of type 2 diabetes mellitus (T2DM). Exercise training has shown positive effects on cardiac function, but its effect on the mitochondria have been insufficiently explored. The aim of this study was to assess the effect of exercise training on mitochondrial function in T2DM hearts. We divided T2DM mice (db/db) into a sedentary and an interval training group at 8 weeks of age and used heterozygote db/+ as controls. After 8 weeks of training, we evaluated mitochondrial structure and function, as well as the levels of mRNA and proteins involved in key metabolic processes from the left ventricle. db/db animals showed decreased oxidative phosphorylation capacity and fragmented mitochondria. Mitochondrial respiration showed a blunted response to Ca2+ along with reduced protein levels of the mitochondrial calcium uniporter. Exercise training ameliorated the reduced oxidative phosphorylation in complex (C) I + II, CII and CIV, but not CI or Ca2+ response. Mitochondrial fragmentation was partially restored. mRNA levels of isocitrate, succinate and oxoglutarate dehydrogenase were increased in db/db mice and normalized by exercise training. Exercise training induced an upregulation of two transcripts of peroxisome proliferator activated receptor gamma coactivator 1 alpha (PGC1α1 and PGC1α4) previously linked to endurance training adaptations and strength training adaptations, respectively. The T2DM heart showed mitochondrial dysfunction at multiple levels and exercise training ameliorated some, but not all mitochondrial dysfunctions. [ABSTRACT FROM AUTHOR]

Published

2019

3. An anti-PDGFRβ aptamer for selective delivery of small therapeutic peptide to cardiac cells.

Author

Romanelli, Alessandra, Affinito, Alessandra, Avitabile, Concetta, Catuogno, Silvia, Ceriotti, Paola, Iaboni, Margherita, Modica, Jessica, Condorelli, Geroloma, and Catalucci, Daniele

Subjects

HEART cells, PLATELET-derived growth factor receptors, APTAMERS, PEPTIDES, CALCIUM channels

Abstract

Small therapeutic peptides represent a promising field for the treatment of pathologies such as cardiac diseases. However, the lack of proper target-selective carriers hampers their translation towards a potential clinical application. Aptamers are cell-specific carriers that bind with high affinity to their specific target. However, some limitations on their conjugation to small peptides and the functionality of the resulting aptamer-peptide chimera exist. Here, we generated a novel aptamer-peptide chimera through conjugation of the PDGFRβ-targeting Gint4.T aptamer to MP, a small mimetic peptide that via targeting of the Cavβ2 subunit of the L-type calcium channel (LTCC) can recover myocardial function in pathological heart conditions associated with defective LTCC function. The conjugation reaction was performed by click chemistry in the presence of N,N,N’,N’,N”-pentamethyldiethylenetriamine as a Cu (I) stabilizing agent in a DMSO-free aqueous buffer. When administered to cardiac cells, the Gint4.T-MP aptamer-peptide chimera was successfully internalized in cells, allowing the functional targeting of MP to LTCC. This approach represents the first example of the use of an internalizing aptamer for selective delivery of a small therapeutic peptide to cardiac cells. [ABSTRACT FROM AUTHOR]

Published

2018

4. Inhalation of peptide-loaded nanoparticles improves heart failure.

Author

Miragoli, Michele, Ceriotti, Paola, Iafisco, Michele, Vacchiano, Marco, Salvarani, Nicolò, Alogna, Alessio, Carullo, Pierluigi, Ramirez-Rodríguez, Gloria Belén, Patrício, Tatiana, Esposti, Lorenzo Degli, Rossi, Francesca, Ravanetti, Francesca, Pinelli, Silvana, Alinovi, Rossella, Erreni, Marco, Rossi, Stefano, Condorelli, Gianluigi, Post, Heiner, Tampieri, Anna, and Catalucci, Daniele

Subjects

HEART failure treatment, RESPIRATORY therapy, PEPTIDES, NANOPARTICLES, CALCIUM phosphate, LABORATORY rodents, THERAPEUTICS

Abstract

Inhalation delivers drug-loaded nanoparticles to the heart, improving cardiac function in murine and porcine models. A puff of particles for the heart: Nanoparticles can be useful for imaging and drug delivery but generally require intravenous injection to reach their targets. Miragoli et al. delivered nanoparticles carrying peptides to the heart by inhalation rather than injection. The inhaled particles reached the heart faster than injected particles and were taken up by cardiomyocytes to improve cardiac function in a mouse model of diabetic cardiomyopathy. In healthy pigs, inhaled particles were also found in heart tissue, suggesting that this minimally invasive method of targeted cardiac delivery could potentially translate to humans. Peptides are highly selective and efficacious for the treatment of cardiovascular and other diseases. However, it is currently not possible to administer peptides for cardiac-targeting therapy via a noninvasive procedure, thus representing scientific and technological challenges. We demonstrate that inhalation of small (<50 nm in diameter) biocompatible and biodegradable calcium phosphate nanoparticles (CaPs) allows for rapid translocation of CaPs from the pulmonary tree to the bloodstream and to the myocardium, where their cargo is quickly released. Treatment of a rodent model of diabetic cardiomyopathy by inhalation of CaPs loaded with a therapeutic mimetic peptide that we previously demonstrated to improve myocardial contraction resulted in restoration of cardiac function. Translation to a porcine large animal model provides evidence that inhalation of a peptide-loaded CaP formulation is an effective method of targeted administration to the heart. Together, these results demonstrate that inhalation of biocompatible tailored peptide nanocarriers represents a pioneering approach for the pharmacological treatment of heart failure. [ABSTRACT FROM AUTHOR]

Published

2018

5. Content of mitochondrial calcium uniporter (MCU) in cardiomyocytes is regulated by microRNA-1 in physiologic and pathologic hypertrophy.

Author

Zaglia, Tania, Ceriotti, Paola, Campo, Antonio, Borile, Giulia, Armani, Andrea, Carullo, Pierluigi, Prando, Valentina, Coppini, Raffaele, Vida, Vladimiro, Stølen, Tomas O., Ulrik, Wisløff, Cerbai, Elisabetta, Stellin, Giovanni, Faggian, Giuseppe, De Stefani, Diego, Sandri, Marco, Rizzuto, Rosario, Lisa, Fabio Di, Pozzan, Tullio, and Catalucci, Daniele

Subjects

CARDIAC hypertrophy, CALCIUM channels, MICRORNA, BETA adrenoceptors, MITOCHONDRIAL physiology, HEART cells, PHYSIOLOGY

Abstract

The mitochondrial Ca2+ uniporter complex (MCUC) is a multimeric ion channel which, by tuning Ca2+ influx into the mitochondrial matrix, finely regulates metabolic energy production. In the heart, this dynamic control of mitochondrial Ca2+ uptake is fundamental for cardiomyocytes to adapt to either physiologic or pathologic stresses. Mitochondrial calcium uniporter (MCU), which is the core channel subunit of MCUC, has been shown to play a critical role in the response to β-adrenoreceptor stimulation occurring during acute exercise. The molecular mechanisms underlying the regulation of MCU, in conditions requiring chronic increase in energy production, such as physiologic or pathologic cardiac growth, remain elusive. Here, we show that microRNA-1 (miR-1), a member of the muscle-specific microRNA (myomiR) family, is responsible for direct and selective targeting of MCU and inhibition of its translation, thereby affecting the capacity of the mitochondrial Ca2+ uptake machinery. Consistent with the role of miR-1 in heart development and cardiomyocyte hypertrophic remodeling, we additionally found that MCU levels are inversely related with the myomiR content, in murine and, remarkably, human hearts from both physiologic (i.e., postnatal development and exercise) and pathologic (i.e., pressure overload) myocardial hypertrophy. Interestingly, the persistent activation of β-adrenoreceptors is likely one of the upstream repressors of miR-1 as treatment with β-blockers in pressure-overloaded mouse hearts prevented its down-regulation and the consequent increase in MCU content. Altogether, these findings identify the miR-1/MCU axis as a factor in the dynamic adaptation of cardiac cells to hypertrophy. [ABSTRACT FROM AUTHOR]

Published

2017

6. Peptidomimetic Targeting of Cavβ2 Overcomes Dysregulation of the L-Type Calcium Channel Density and Recovers Cardiac Function.

Author

Rusconi, Francesca, Ceriotti, Paola, Miragoli, Michele, Carullo, Pierluigi, Salvarani, Nicolò, Rocchetti, Marcella, Di Pasquale, Elisa, Rossi, Stefano, Tessari, Maddalena, Caprari, Silvia, Cazade, Magali, Kunderfranco, Paolo, Chemin, Jean, Bang, Marie-Louise, Polticelli, Fabio, Zaza, Antonio, Faggian, Giuseppe, Condorelli, Gianluigi, and Catalucci, Daniele

Published

2016

7. Abstract 182.

Author

Rusconi, Francesca, Miragoli, Michele, Di Pasquale, Elisa, Rocchetti, Marcella, Ceriotti, Paola, Carullo, Pierluigi, Caprari, Silvia, Viggiani, Giacomo, Cazade, Magali, Chemin, Jean, Bang, Marie-Louise, Polticelli, Fabio, Zaza, Antonio, Condorelli, Gianluigi, and Catalucci, Daniele

Published

2014