Dulsat Gemma, Palomeras Sonia, Cortada Eric, Riuró Helena, Brugada Ramon, Vergés Marcel
Cardiovascular Genetics Group, Girona Biomedical Research Institute (IDIBGI), Salt, Girona, 17190, Spain.
Biomedical Research Networking Center on Cardiovascular Diseases (CIBERCV), ISCIII, Madrid, 28029, Spain.
Biol Cell. 2017 Jul;109(7):273-291. doi: 10.1111/boc.201600085.
Cardiac channelopathies arise by mutations in genes encoding ion channel subunits. One example is Brugada Syndrome (BrS), which causes arrhythmias and sudden death. BrS is often associated with mutations in SCN5A, encoding Na 1.5, the α subunit of the major cardiac voltage-gated sodium channel. This channel forms a protein complex including one or two associated β subunits as well as other proteins.
We analysed regulation of Na 1.5 localisation and trafficking by β2, specifically, Na 1.5 arrival to the cell surface. We used polarised Madin-Darby canine kidney (MDCK) cells and mouse atria-derived HL-1 cells, which retain phenotypic features of adult cardiomyocytes. In both, Na 1.5 was found essentially intracellular, mainly in the endoplasmic reticulum, whereas β2 localised to the plasma membrane, and was restricted to the apical surface in MDCK cells. A fraction of β2 interacted with Na 1.5, despite their limited overlap. Importantly, β2 promoted Na 1.5 localisation to the cell surface. Both β2 WT and the BrS-associated mutation D211G (substitution of Asp for Gly) effectively reached the plasma membrane. Strikingly, however, β2 D211G was defective in promoting Na 1.5 surface localisation.
Our data sustain that β2 promotes surface localisation of Na 1.5, which can be affected due to β2 mutations associated with channelopathies.
Our findings add to the understanding of β2 role in Na 1.5 trafficking and localisation, which must influence cell excitability and electrical coupling in the heart. This study will contribute to knowledge on development of arrhythmias.
心脏离子通道病由编码离子通道亚基的基因突变引起。一个例子是 Brugada 综合征(BrS),它会导致心律失常和猝死。BrS 通常与 SCN5A 基因突变有关,SCN5A 编码主要的心脏电压门控钠通道的α亚基 Na 1.5。该通道形成一种蛋白质复合物,包括一个或两个相关的β亚基以及其他蛋白质。
我们分析了β2对 Na 1.5 定位和运输的调节作用,特别是 Na 1.5 到达细胞表面的情况。我们使用了极化的 Madin-Darby 犬肾(MDCK)细胞和源自小鼠心房的 HL-1 细胞,这些细胞保留了成年心肌细胞的表型特征。在这两种细胞中,Na 1.5 基本上位于细胞内,主要在内质网中,而β2 定位于质膜,并且在 MDCK 细胞中仅限于顶端表面。尽管β2 与 Na 1.5 的重叠有限,但仍有一部分β2 与 Na 1.5 相互作用。重要的是,β2 促进了 Na 1.5 向细胞表面的定位。β2野生型和与 BrS 相关的突变 D211G(天冬氨酸被甘氨酸取代)都能有效地到达质膜。然而,令人惊讶的是,β2 D211G 在促进 Na 1.5 表面定位方面存在缺陷。
我们的数据支持β2促进 Na 1.5 表面定位的观点,与离子通道病相关的β2 突变可能会影响这一过程。
我们的研究结果有助于理解β2在 Na 1.5 运输和定位中的作用,这必然会影响心脏中的细胞兴奋性和电偶联。这项研究将有助于了解心律失常的发生机制。
