截断对TRPM7通道活性的影响。

Zhuqing Xie, Nashat Abumaria
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引用次数: 0

摘要

瞬时受体电位美司他汀样7(TRPM7)在各种生理和病理过程中起着关键作用。TRPM7通道活性受不同因素的调节。不同结构域的切割对通道活性的影响仍然未知。在这里,我们构建了几个TRPM7克隆,并探讨了在不同位置截短小鼠TRPM7对两种细胞系中离子通道活性的影响。我们在转染和未转染的细胞中比较了克隆与全长TRPM7和天然TRPM7的活性。我们还表达了荧光标记的截短克隆,以检查其蛋白质稳定性和膜靶向性。我们发现截短激酶结构域会导致TRPM7通道活性降低。激酶之外的进一步截短(富含丝氨酸/苏氨酸的结构域和/或卷曲螺旋结构域)没有导致通道活性的进一步降低。两个缺乏TRP结构域或美司他丁同源结构域的截短克隆具有完全无功能的通道,这显然是由于蛋白质稳定性的破坏。我们确定了具有可测量通道活性的TRPM7的最短结构。我们发现仅含有S5和S6结构域的截短的TRPM7保留了一些通道活性。将TRP结构域添加到S5-S6导致通道活性的显著增加。最后,我们的分析表明,TRPM7外向电流比内向电流对截断更敏感。我们的数据深入了解了在不同位置截短TRPM7对通道功能的影响,强调了不同结构域在影响通道活性、蛋白质稳定性和/或膜靶向方面的重要性。
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Effect of truncation on TRPM7 channel activity.

Transient receptor potential melastatin-like 7 (TRPM7) is a key player in various physiological and pathological processes. TRPM7 channel activity is regulated by different factors. The effects of cleavage of different domains on channel activity remain unknown. Here, we constructed several TRPM7 clones and explored the effects of truncating the mouse TRPM7 at different locations on the ion channel activity in two cell lines. We compared the clones' activity with the full-length TRPM7 and the native TRPM7 in transfected and untransfected cells. We also expressed fluorescently tagged truncated clones to examine their protein stability and membrane targeting. We found that truncating the kinase domain induced reduction in TRPM7 channel activity. Further truncations beyond the kinase (serine/threonine rich domain and/or coiled-coil domain) did not result in further reductions in channel activity. Two truncated clones lacking the TRP domain or the melastatin homology domain had a completely nonfunctional channel apparently due to disruption of protein stability. We identified the shortest structure of TRPM7 with measurable channel activity. We found that the truncated TRPM7 containing only S5 and S6 domains retained some channel activity. Adding the TRP domain to the S5-S6 resulted in a significant increase in channel activity. Finally, our analysis showed that TRPM7 outward currents are more sensitive to truncations than inward currents. Our data provide insights on the effects of truncating TRPM7 at different locations on the channel functions, highlighting the importance of different domains in impacting channel activity, protein stability, and/or membrane targeting.

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