Your search keyword '"Adrien Martinotti"' showing total 4 results

1. BCL2L13 at endoplasmic reticulum-mitochondria contact sites regulates calcium homeostasis to maintain skeletal muscle function

Author

Dogan Grepper, Cassandra Tabasso, Nadège Zanou, Axel K.F. Aguettaz, Mauricio Castro-Sepulveda, Dorian V. Ziegler, Sylviane Lagarrigue, Yoan Arribat, Adrien Martinotti, Ammar Ebrahimi, Jean Daraspe, Lluis Fajas, and Francesca Amati

Subjects

pharmacology, cell biology, Science

Abstract

Summary: The physical connection between mitochondria and endoplasmic reticulum (ER) is an essential signaling hub to ensure organelle and cellular functions. In skeletal muscle, ER-mitochondria calcium (Ca2+) signaling is crucial to maintain cellular homeostasis during physical activity. High expression of BCL2L13, a member of the BCL-2 family, was suggested as an adaptive response in endurance-trained human subjects. In adult zebrafish, we found that the loss of Bcl2l13 impairs skeletal muscle structure and function. Ca2+ signaling is altered in Bcl2l13 knockout animals and mitochondrial complexes activity is decreased. Organelle fractioning in mammalian cells shows BCL2L13 at mitochondria, ER, and mitochondria-associated membranes. ER-mitochondria contact sites number is not modified by BCL2L13 modulation, but knockdown of BCL2L13 in C2C12 cells changes cytosolic Ca2+ release and mitochondrial Ca2+ uptake. This suggests that BCL2L13 interaction with mitochondria and ER, and its role in Ca2+ signaling, contributes to proper skeletal muscle function.

Published

2024

2. Methodological advancements in organ-specific ectopic lipid quantitative characterization: Effects of high fat diet on muscle and liver intracellular lipids

Author

Dogan Grepper, Cassandra Tabasso, Axel K.F. Aguettaz, Adrien Martinotti, Ammar Ebrahimi, Sylviane Lagarrigue, and Francesca Amati

Subjects

Lipid droplets, Intrahepatic lipids, Intramyocellular lipids, Fatty liver, Lipid metabolism, Obesity, Internal medicine, RC31-1245

Abstract

Objective: Ectopic lipid accumulation is a hallmark of metabolic diseases, linking obesity to non-alcoholic fatty liver disease, insulin resistance and diabetes. The use of zebrafish as a model of obesity and diabetes is raising due to the conserved properties of fat metabolism between humans and zebrafish, the homologous genes regulating lipid uptake and transport, the implementation of the ‘3R’s principle and their cost-effectiveness. To date, a method allowing the conservation of lipid droplets (LDs) and organs in zebrafish larvae to image ectopic lipids is not available. Our objectives were to develop a novel methodology to quantitatively evaluate organ-specific LDs, in skeletal muscle and liver, in response to a nutritional perturbation. Methods: We developed a novel embedding and cryosectioning protocol allowing the conservation of LDs and organs in zebrafish larvae. To establish the quantitative measures, we used a three-arm parallel nutritional intervention design. Zebrafish larvae were fed a control diet containing 14% of nutritional fat or two high fat diets (HFDs) containing 25 and 36% of dietary fats. In muscle and liver, LDs were characterized using immunofluorescence confocal microscopy. In liver, intrahepatocellular lipids were discriminated from intrasinusoid lipids. To complete liver characteristics, fibrosis was identified with Masson’s Trichrome staining. Finally, to confirm the conservation and effect of HFD, molecular players of fat metabolism were evaluated by RT-qPCR. Results: The cryosections obtained after setting up the embedding and cryopreservation method were of high quality, preserving tissue morphology and allowing the visualization of ectopic lipids. Both HFDs were obesogenic, without modifying larvae survival or development. Neutral lipid content increased with time and augmented dietary fat. Intramuscular LD volume density increased and was explained by an increase in LDs size but not in numbers. Intrahepatocellular LD volume density increased and was explained by an increased number of LDs, not by their increased size. Sinusoid area and lipid content were both increased. Hepatic fibrosis appeared with both HFDs. We observed alterations in the expression of genes associated with LD coating proteins, LD dynamics, lipogenesis, lipolysis and fatty acid oxidation. Conclusions: In this study, we propose a reproducible and fast method to image zebrafish larvae without losing LD quality and organ morphology. We demonstrate the impact of HFD on LD characteristics in liver and skeletal muscle accompanied by alterations of key players of fat metabolism. Our observations confirm the evolutionarily conserved mechanisms in lipid metabolism and reveal organ specific adaptations. The methodological advancements proposed in this work open the doors to study organelle adaptations in obesity and diabetes related research such as lipotoxicity, organelle contacts and specific lipid depositions.

Published

2023

3. Comparing radiolytic production of H

Author

Houda, Kacem, Serena, Psoroulas, Gael, Boivin, Michael, Folkerts, Veljko, Grilj, Tony, Lomax, Adrien, Martinotti, David, Meer, Jonathan, Ollivier, Benoit, Petit, Sairos, Safai, Ricky A, Sharma, Michele, Togno, Marta, Vilalta, Damien C, Weber, and Marie-Catherine, Vozenin

Subjects

Proton Therapy, Animals, Electrons, Radiotherapy Dosage, Hydrogen Peroxide, Protons, Zebrafish

Abstract

The physico-chemical and biological response to conventional and UHDR electron and proton beams was investigated, along with conventional photons. The temporal structure and nature of the beam affected both, with electron beam at ≥1400 Gy/s and proton beam at 0.1 and 1260 Gy/s found to be isoefficient at sparing zebrafish embryos.

Published

2022

4. Comparing radiolytic production of H2O2 and development of Zebrafish embryos after ultra high dose rate exposure with electron and transmission proton beams

Author

Houda Kacem, Serena Psoroulas, Gael Boivin, Michael Folkerts, Veljko Grilj, Tony Lomax, Adrien Martinotti, David Meer, Jonathan Ollivier, Benoit Petit, Sairos Safai, Ricky A. Sharma, Michele Togno, Marta Vilalta, Damien C. Weber, and Marie-Catherine Vozenin

Subjects

Oncology, 610 Medicine & health, Radiology, Nuclear Medicine and imaging, Hematology

Abstract

The physico-chemical and biological response to conventional and UHDR electron and proton beams was investigated, along with conventional photons. The temporal structure and nature of the beam affected both, with electron beam at ≥1400 Gy/s and proton beam at 0.1 and 1260 Gy/s found to be isoefficient at sparing zebrafish embryos.

Published

2022