Brahmajothi M V, Morales M J, Liu S, Rasmusson R L, Campbell D L, Strauss H C
Department of Pharmacology, Duke University Medical Center, Durham, NC 27710, USA.
Circ Res. 1996 Jun;78(6):1083-9. doi: 10.1161/01.res.78.6.1083.
The molecular basis of K+ currents that generate repolarization in the heart is uncertain. In part, this reflects the similar functional properties different K+ channel clones display when heterologously expressed, in addition to the molecular diversity of the voltage-gated K+ channel family. To determine the identity, regional distribution, and cellular distribution of voltage-sensitive K+ channel mRNA subunits expressed in ferret heart, we used fluorescent labeled oligonucleotide probes to perform in situ hybridization studies on enzymatically isolated myocytes from the sinoatrial (SA) node, right and left atria, right and left ventricles, and interatrial and interventricular septa. The most widely distributed K+ channel transcripts in the ferret heart were Kv1.5 (present in 69.3% to 85.6% of myocytes tested, depending on the anatomic region from which myocytes were isolated) and Kv1.4 (46.1% to 93.7%), followed by kv1.2, Kv2.1, and Kv4.2. Surprisingly, many myocytes contain transcripts for Kv1.3, Kv2.2, Kv4.1, Kv5.1, and members of the Kv3 family. Kv1.1, Kv1.6, and Kv6.1, which were rarely expressed in working myocytes, were more commonly expressed in SA nodal cells. IRK was expressed in ventricular (84.3% to 92.8%) and atrial (52.4% to 64.0%) cells but was nearly absent (6.6%) in SA nodal cells; minK was most frequently expressed in SA nodal cells (33.7%) as opposed to working myocytes (10.3% to 29.3%). Two gene products implicated in long-QT syndrome, ERG and KvLQT1, were common in all anatomic regions (41.1% to 58.2% and 52.1% to 71.8%, respectively). These results show that the diversity of K+ channel mRNA in heart is greater than previously suspected and that the molecular basis of K+ channels may vary from cell to cell within distinct regions of the heart and also between major anatomic regions.
在心脏中产生复极化的钾离子电流的分子基础尚不确定。部分原因在于,除了电压门控钾离子通道家族的分子多样性外,不同的钾离子通道克隆在异源表达时也表现出相似的功能特性。为了确定雪貂心脏中表达的电压敏感性钾离子通道mRNA亚基的身份、区域分布和细胞分布,我们使用荧光标记的寡核苷酸探针,对从窦房结、左右心房、左右心室以及房间隔和室间隔酶解分离的心肌细胞进行原位杂交研究。雪貂心脏中分布最广泛的钾离子通道转录本是Kv1.5(根据分离心肌细胞的解剖区域不同,在测试的心肌细胞中占69.3%至85.6%)和Kv1.4(46.1%至93.7%),其次是Kv1.2、Kv2.1和Kv4.2。令人惊讶的是,许多心肌细胞含有Kv1.3、Kv2.2、Kv4.1、Kv5.1以及Kv3家族成员的转录本。在工作心肌细胞中很少表达的Kv1.1、Kv1.6和Kv6.1,在窦房结细胞中更常见。内向整流钾通道(IRK)在心室细胞(84.3%至92.8%)和心房细胞(52.4%至64.0%)中表达,但在窦房结细胞中几乎不存在(6.6%);微小钾通道(minK)最常在窦房结细胞(33.7%)中表达,而在工作心肌细胞中表达较少(10.3%至29.3%)。与长QT综合征相关的两个基因产物,即ether-à-go-go相关基因(ERG)和KvLQT1,在所有解剖区域都很常见(分别为41.1%至58.2%和52.1%至71.8%)。这些结果表明,心脏中钾离子通道mRNA的多样性比之前怀疑的更大,并且钾离子通道的分子基础可能在心脏不同区域内的细胞之间以及主要解剖区域之间存在差异。
