Your search keyword '"Salah Sommakia"' showing total 3 results

1. Abstract P467: Cardiac-specific Deletion Of Voltage Dependent Anion Channel 2 Leads To Dilated Cardiomyopathy By Altering Calcium Homeostasis

Author

Johann Schredelseker, Dipayan Chaudhuri, Ohyun Kwon, Dinesh K. A. Ramadurai, Kira Steinhorst, Dallen Calder, Salah Sommakia, Rachit Badolia, Thirupura S. Shankar, Emily Cheng, Sutip Navankasattusas, Aspasia Thodou Krokidi, Kenneth W. Spitzer, Frank B. Sachse, Stavros G. Drakos, Jing Ling, and Russel S. Richardson

Subjects

Calcium metabolism, Voltage-dependent anion channel, biology, Physiology, Chemistry, medicine, biology.protein, Dilated cardiomyopathy, Cardiology and Cardiovascular Medicine, medicine.disease, Cell biology

Abstract

Voltage dependent anion channel 2 (VDAC2) is a mitochondrial outer membrane porin known to play a significant role in apoptosis and calcium signaling. Abnormalities in cellular calcium homeostasis often leads to electrical and contractile dysfunction and can cause dilated cardiomyopathy and heart failure. Previous literature suggests that improving mitochondrial calcium uptake via VDAC2 rescues arrhythmia phenotypes in genetic models of impaired cellular calcium signaling. However, the direct role of VDAC2 in intracellular calcium signaling and cardiac function is not well understood. To elucidate the role of VDAC2 in calcium homeostasis, we generated a cardiac-specific deletion of Vdac2 in mice. Our results indicate that loss of VDAC2 in the myocardium during development causes severe impairment in excitation-contraction coupling by reducing mitochondrial calcium uptake (n=3, p0 ) and rate of calcium uptake by SERCA2a [tau(msec)] compared to control mice (N=3, WT=54, KO=38, p0 ) and p

Published

2021

2. Abstract 567: Fgf21 as a Biomarker for Metabolic Stress in Heart Failure

Author

Naredos Almaw, Dipayan Chaudhuri, Elizabeth Nguyen, Dinesh K. A. Ramadurai, Thirupura S. Shankar, Salah Sommakia, Stavros G. Drakos, Sutip Navankasattusas, and Robert A. Campbell

Subjects

Fight-or-flight response, FGF21, Physiology, business.industry, Heart failure, medicine, Regulator, Biomarker (medicine), Metabolic Stress, Cardiology and Cardiovascular Medicine, medicine.disease, business, Bioinformatics

Abstract

FGF21, an important metabolic regulator, has recently been suggested as a biomarker for heart failure (HF). FGF21 is involved in the integrated mitochondrial stress response, and has been shown to be upregulated with mitochondrial DNA damage, which occurs more frequently in dilated cardiomyopathy. In this study, we investigated whether FGF21 can be used as a biomarker for metabolic stress in HF. We collected blood and cardiac tissue samples from ischemic and non-ischemic HF patients who have undergone VAD transplantation. We also collected blood and tissue from mice with HF due to 1) combination of transverse aortic constriction and coronary artery ligation (TAC+Lig) or 2) cardiac-specific knockout of the mitochondrial transcription factor A (Tfam). Serum FGF21 levels were measured using Enzyme-linked immunosorbent assay (ELISA). Messenger RNA was extracted from the tissue and FGF21 gene expression was measured using real-time quantitative PCR (qPCR). Immunohistochemical staining was performed on tissue sections (either paraffin embedded or frozen) to observe FGF21 levels. Serum FGF21 was elevated in human HF patients compared to healthy controls, as well as in both mouse models of HF. In human patients, cardiac FGF21 gene expression was upregulated 2.2-fold compared to donors. In the TAC+Lig mouse model we observed a 3.37-fold increase, while the Tfam knockout model which has severe mitochondrial damage exhibited a 218-fold increase in cardiac FGF21 gene expression. Further qPCR assays revealed changes in FGF21 gene expression in the liver and white fat of TFAM-KO, indicating metabolic stress on other organs resulting from HF. In conclusion, serum FGF21 is elevated in multiple models of HF, and appears to have both cardiac and extra cardiac sources. Future work will investigate 1) whether there is a correlation between FGF21 levels and mitochondrial damage, and 2) the signaling pathway resulting in metabolic stress to other organs in HF.

Published

2019

3. Abstract 437: Mitochondrial Cardiomyopathies Feature Enhanced Mitochondrial Calcium Signaling

Author

Salah Sommakia, Patrick Houlihan, Sadiki Deane, Judith Simcox, Claudio Villanueva, David Clapham, and Dipayan Chaudhuri

Subjects

Physiology, Cardiology and Cardiovascular Medicine

Abstract

Mitochondrial diseases often feature early onset of dilated cardiomyopathy, due to the large energetic demand placed by the heart. Among regulators of mitochondrial respiration, we focus on calcium, which potently stimulates ATP synthesis. We assessed the hypothesis that cells boost mitochondrial calcium to stimulate respiration as this declines in mitochondrial cardiomyopathies. To this end, we studied mice that develop a neonatal, severe cardiomyopathy caused by cardiac-specific knockout (KO) of mitochondrial transcription factor A ( Tfam ). Such deletion impairs transcription of mitochondrial DNA, which encodes multiple subunits of the electron transport chain (ETC). Tfam KO mice exhibited a dilated cardiomyopathy, with decreased fractional shortening and increased LV diameters, and had marked inhibition of multiple ETC complexes. We determined that Tfam KO mitochondria took up calcium twice as fast as mitochondria from littermate controls, while calcium efflux was approximately 70% slower. Whole-mitoplast voltage clamp revealed that the enhanced calcium uptake was due to an increase in the current carried by the uniporter. Furthermore, the larger uniporter current reflected increased amounts of uniporter subunit proteins. This occurred despite a reduction in the transcripts of genes encoding these subunits, suggesting a post-translational mechanism for the enhanced uniporter stability. Finally, we found that the rate of ADP-stimulated oxygen consumption in calcium-free solution was 50% less in the Tfam KO mitochondria compared to controls, but increased substantially more, nearly to control levels, when calcium was present (2.5-fold increase for KO versus 1.7-fold for control). In conclusion, enhanced mitochondrial calcium signaling in a mitochondrial cardiomyopathy model may serve to compensate for energetic failure.

Published

2017