Characterisation of infantile cardiomyopathy in Alström syndrome using ALMS1 knockout induced pluripotent stem cell derived cardiomyocyte model

IF 3.7 2区 生物学 Q2 ENDOCRINOLOGY & METABOLISM
Leena Patel , Ashwin Roy , Jonathan Barlow , Christopher O'Shea , Daniel Nieves , Amar J. Azad , Caitlin Hall , Ben Davies , Phalguni Rath , Davor Pavlovic , Ashish Chikermane , Tarekegn Geberhiwot , Richard P. Steeds , Katja Gehmlich
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Abstract

Alström syndrome (AS) is an inherited rare ciliopathy characterised by multi-organ dysfunction and premature cardiovascular disease. This may manifest as an infantile-onset dilated cardiomyopathy with significant associated mortality. An adult-onset restrictive cardiomyopathy may also feature later in life. Loss of function pathogenic variants in ALMS1 have been identified in AS patients, leading to a lack of ALMS1 protein. The biological role of ALMS1 is unknown, particularly in a cardiovascular context. To understand the role of ALMS1 in infantile cardiomyopathy, the reduction of ALMS1 protein seen in AS patients was modelled using human induced pluripotent stem cell-derived cardiomyocytes (iPSC-CMs), in which ALMS1 was knocked out. MuscleMotion analysis and calcium optical mapping experiments suggest that ALMS1 knockout (KO) cells have increased contractility, with altered calcium extrusion and impaired calcium handling dynamics compared to wildtype (WT) counterparts. Seahorse metabolic assays showed ALMS1 knockout iPSC-CMs had increased glycolytic and mitochondrial respiration rates, with ALMS1 knockout cells portraying increased energetic demand and respiratory capacity than WT counterparts. Using senescence associated β-galactosidase (SA-β gal) staining assay, we identified increased senescence of ALMS1 knockout iPSC-CMs. Overall, this study provides insights into the molecular mechanisms in AS, particularly the role of ALMS1 in infantile cardiomyopathy in AS, using iPSC-CMs as a ‘disease in a dish’ model to provide insights into multiple aspects of this complex disease.

利用 ALMS1 基因敲除诱导多能干细胞衍生的心肌细胞模型描述阿尔斯特罗姆综合征婴儿心肌病的特征。
阿尔斯特罗姆综合征(AS)是一种遗传性罕见纤毛病,以多器官功能障碍和过早出现心血管疾病为特征。这种病可能表现为婴儿期发病的扩张型心肌病,死亡率很高。成年后也可能出现限制性心肌病。在强直性脊柱炎患者中发现了 ALMS1 的功能缺失致病变体,导致 ALMS1 蛋白缺乏。ALMS1的生物学作用尚不清楚,尤其是在心血管方面。为了了解ALMS1在婴幼儿心肌病中的作用,我们使用敲除了ALMS1的人类诱导多能干细胞衍生心肌细胞(iPSC-CMs)模拟了AS患者体内ALMS1蛋白的减少。肌肉运动分析和钙光学映射实验表明,与野生型(WT)细胞相比,ALMS1基因敲除(KO)细胞的收缩力增强,钙挤出发生改变,钙处理动力学受损。海马代谢测定显示,ALMS1基因敲除iPSC-CMs的糖酵解和线粒体呼吸速率增加,ALMS1基因敲除细胞的能量需求和呼吸能力均高于WT细胞。通过衰老相关的β-半乳糖苷酶(SA-β gal)染色检测,我们发现 ALMS1 基因敲除 iPSC-CMs 的衰老程度增加。总之,这项研究深入揭示了强直性脊柱炎的分子机制,特别是ALMS1在强直性脊柱炎婴儿心肌病中的作用,利用iPSC-CMs作为 "皿中疾病 "模型,深入揭示了这种复杂疾病的多个方面。
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来源期刊
Molecular genetics and metabolism
Molecular genetics and metabolism 生物-生化与分子生物学
CiteScore
5.90
自引率
7.90%
发文量
621
审稿时长
34 days
期刊介绍: Molecular Genetics and Metabolism contributes to the understanding of the metabolic and molecular basis of disease. This peer reviewed journal publishes articles describing investigations that use the tools of biochemical genetics and molecular genetics for studies of normal and disease states in humans and animal models.
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