Expression of tropomyosin in relation to myofibrillogenesis in axolotl hearts.

IF 2 Regenerative Medicine Research Pub Date : 2013-12-04 eCollection Date: 2013-12-01 DOI:10.1186/2050-490X-1-8
Robert W Zajdel, Matthew D McLean, Syamalima Dube, Dipak K Dube
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引用次数: 4

Abstract

The anatomy, function and embryonic development of the heart have been of interest to clinicians and researchers alike for centuries. A beating heart is one of the key criteria in defining life or death in humans. An understanding of the multitude of genetic and functional elements that interplay to form such a complex organ is slowly evolving with new genetic, molecular and experimental techniques. Despite the need for ever more complex molecular techniques some of our biggest leaps in knowledge come from nature itself through observations of mutations that create natural defects in function. Such a natural mutation is found in the Mexican axolotl, Ambystoma mexicanum. It is a facultative neotenous salamander well studied for its ability to regenerate severed limbs and tail. Interestingly it also well suited to studying segmental heart development and differential sarcomere protein expression due to a naturally occurring mendelian recessive mutation in cardiac mutant gene "c". The resultant mutants are identified by their failure to beat and can be studied for extended periods before they finally die due to lack of circulation. Studies have shown a differential expression of tropomyosin between the conus and the ventricle indicating two different cardiac segments. Tropomyosin protein, but not its transcript have been found to be deficient in mutant ventricles and sarcomere formation can be rescued by the addition of TM protein or cDNA. Although once thought to be due to endoderm induction our findings indicate a translational regulatory mechanism that may ultimately control the level of tropomyosin protein in axolotl hearts.

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原肌球蛋白在蝾螈心脏中与肌纤维形成有关的表达。
几个世纪以来,心脏的解剖、功能和胚胎发育一直是临床医生和研究人员感兴趣的问题。心脏跳动是决定人类生死的关键标准之一。随着新的遗传、分子和实验技术的发展,对形成如此复杂器官的众多遗传和功能因素的理解正在缓慢地发展。尽管需要越来越复杂的分子技术,但我们在知识方面的一些最大飞跃来自于自然界本身,通过观察产生自然功能缺陷的突变。这种自然突变在墨西哥蝾螈Ambystoma mexicanum中被发现。它是一种兼性幼生蝾螈,因其能够再生切断的四肢和尾巴而得到了很好的研究。有趣的是,由于心脏突变基因“c”的自然发生孟德尔隐性突变,它也非常适合于研究段性心脏发育和差异肌节蛋白表达。由此产生的突变体可以通过它们无法跳动来识别,并且可以在它们最终因缺乏循环而死亡之前进行长时间的研究。研究表明,原肌球蛋白在圆锥和心室之间的差异表达表明两个不同的心脏节段。原肌球蛋白蛋白(Tropomyosin)在突变脑室中缺失,但其转录物不缺失,通过添加TM蛋白或cDNA可以挽救肌瘤的形成。虽然曾经被认为是由于内胚层诱导,但我们的研究结果表明,一种翻译调节机制可能最终控制美西螈心脏中原肌球蛋白的水平。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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Regenerative Medicine Research
Regenerative Medicine Research MEDICINE, RESEARCH & EXPERIMENTAL-
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