Myocardial SERCA2 Protects Against Cardiac Damage and Dysfunction Caused by Inhaled Bromine.

IF 3.1 3区 医学 Q2 PHARMACOLOGY & PHARMACY
Juan Xavier Masjoan Juncos, Fahad Nadeem, Shazia Shakil, Malik El-Husari, Iram Zafar, William E Louch, Ganesh V Halade, Ahmed Zaky, Aftab Ahmad, Shama Ahmad
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引用次数: 0

Abstract

Myocardial sarcoendoplasmic reticulum calcium ATPase 2 (SERCA2) activity is critical for heart function. We have demonstrated that inhaled halogen (chlorine or bromine) gases inactivate SERCA2, impair calcium homeostasis, increase proteolysis, and damage the myocardium ultimately leading to cardiac dysfunction. To further elucidate the mechanistic role of SERCA2 in halogen-induced myocardial damage, we used bromine-exposed cardiac-specific SERCA2 knockout (KO) mice [tamoxifen-administered SERCA2 (flox/flox) Tg (αMHC-MerCreMer) mice] and compared them to the oil-administered controls. We performed echocardiography and hemodynamic analysis to investigate cardiac function 24 hours after bromine (600 ppm for 30 minutes) exposure and measured cardiac injury markers in plasma and proteolytic activity in cardiac tissue and performed electron microscopy of the left ventricle (LV). Cardiac-specific SERCA2 knockout mice demonstrated enhanced toxicity to bromine. Bromine exposure increased ultrastructural damage, perturbed LV shape geometry, and demonstrated acutely increased phosphorylation of phospholamban in the KO mice. Bromine-exposed KO mice revealed significantly enhanced mean arterial pressure and sphericity index and decreased LV end diastolic diameter and LV end systolic pressure when compared with the bromine-exposed control FF mice. Strain analysis showed loss of synchronicity, evidenced by an irregular endocardial shape in systole and irregular vector orientation of contractile motion across different segments of the LV in KO mice, both at baseline and after bromine exposure. These studies underscore the critical role of myocardial SERCA2 in preserving cardiac ultrastructure and function during toxic halogen gas exposures. SIGNIFICANCE STATEMENT: Due to their increased industrial production and transportation, halogens such as chlorine and bromine pose an enhanced risk of exposure to the public. Our studies have demonstrated that inhalation of these halogens leads to the inactivation of cardiopulmonary SERCA2 and results in calcium overload. Using cardiac-specific SERCA2 KO mice, these studies further validated the role of SERCA2 in bromine-induced myocardial injury. These studies highlight the increased susceptibility of individuals with pathological loss of cardiac SERCA2 to the effects of bromine.

心肌 SERCA2 可防止吸入溴引起的心脏损伤和功能障碍。
心肌肌浆网钙离子 ATP 酶 2(SERCA2)的活性对心脏功能至关重要。我们已经证明,吸入的卤素(氯或溴)气体会使 SERCA2 失活,损害钙稳态,增加蛋白分解,损伤心肌,最终导致心脏功能障碍。为了进一步阐明 SERCA2 在卤素诱导的心肌损伤中的机理作用,我们利用暴露于溴气的心脏特异性 SERCA2 基因敲除(KO)小鼠(他莫昔芬给药 SERCA(flox/flox) Tg(aMHC-MerCreMer) 小鼠),并将它们与给油对照组(FF)进行比较。溴(600 ppm,30 分钟)暴露 24 小时后,我们进行了超声心动图和血流动力学分析以研究心脏功能,并测量了血浆中的心脏损伤标记物和心脏组织中的蛋白水解活性,还对左心室(LV)进行了电子显微镜检查。心脏特异性 SERCA2 基因敲除小鼠对溴的毒性增强。溴暴露增加了超微结构损伤,扰乱了左心室的几何形状,并显示出 KO 小鼠体内磷脂兰班的磷酸化急性增加。与暴露于溴的对照 FF 小鼠相比,暴露于溴的 KO 小鼠的平均动脉压(MAP)和球形指数明显升高,左心室舒张末期直径 LVEDD 和左心室收缩末期压力(LVESP)下降。应变分析表明,KO 小鼠在收缩期心内膜形状不规则,收缩运动在左心室不同区段的矢量方向不规则,这表明小鼠在基线期和溴暴露后都丧失了同步性。这些研究强调了心肌 SERCA2 在有毒卤素气体暴露期间保护心脏超微结构和功能的关键作用。意义声明 由于工业生产和运输的增加,氯和溴等卤素给公众带来了更大的暴露风险。我们的研究表明,吸入这些卤素会导致心肺 SERCA2 失活,造成钙超载。通过使用心脏特异性 SERCA2 基因敲除小鼠,这些研究进一步验证了 SERCA2 在溴诱导的心肌损伤中的作用。这些研究突出表明,心脏 SERCA2 病理缺失的个体更容易受到溴的影响。
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来源期刊
CiteScore
6.90
自引率
0.00%
发文量
115
审稿时长
1 months
期刊介绍: A leading research journal in the field of pharmacology published since 1909, JPET provides broad coverage of all aspects of the interactions of chemicals with biological systems, including autonomic, behavioral, cardiovascular, cellular, clinical, developmental, gastrointestinal, immuno-, neuro-, pulmonary, and renal pharmacology, as well as analgesics, drug abuse, metabolism and disposition, chemotherapy, and toxicology.
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