Emma M. Wade, Elizabeth A. Goodin, Tim Morgan, Stephana Pereira, Adele G. Woolley, Zandra A. Jenkins, Philip B. Daniel, Stephen P. Robertson
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Hinge-1 protects cells from otherwise destructive forces, and the products of calpain cleavage are involved in critical cellular signalling processes, such as survival during hypoxia. Pathogenic variants in <i>FLNA</i> encoding Filamin A, including those that remove the hinge-1 domain, cause a wide range of survivable developmental disorders. In contrast, complete loss of function of this gene is embryonic lethal in human and mouse.</p>\n </section>\n \n <section>\n \n <h3> Methods and Results</h3>\n \n <p>In this study, we show that removing filamin A hinge-1 from mouse (<i>Flna</i><sup><i>ΔH1</i></sup>), while preserving its expression level leads to no obvious developmental phenotype. Detailed characterisation of the skeletons of <i>Flna</i><sup><i>ΔH1</i></sup> mice showed no skeletal phenotype reminiscent of that found in the <i>FLNA-</i>causing skeletal dysplasia. 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引用次数: 0
摘要
引言丝蛋白是一种细胞骨架结合蛋白,可将肌动蛋白动态交联成正交网络或捆绑成应力纤维。丝蛋白的结构域特征非常明显,有一个 N 端肌动蛋白结合区,其后是 24 个类似免疫球蛋白的重复单元。重复结构域被称为铰链-1 和铰链-2 的两个低复杂性区域分隔成不同的片段。铰链-1 的作用尤其被认为对蛋白质的功能至关重要,因为它为原本僵硬的蛋白质提供了灵活性,并且是钙蛋白酶的裂解目标。铰链-1 保护细胞免受其他破坏力的影响,钙蛋白酶裂解的产物参与了关键的细胞信号传递过程,如缺氧时的存活。编码 Filamin A 的 FLNA 中的致病变体,包括那些去除了铰链-1 结构域的变体,会导致多种可存活的发育障碍。相比之下,该基因完全丧失功能会导致人类和小鼠胚胎死亡:在这项研究中,我们发现从小鼠体内移除丝胺A铰链-1(FlnaΔH1),同时保留其表达水平,不会导致明显的发育表型。对FlnaΔH1小鼠骨骼的详细表征显示,其骨骼表型与FLNA导致的骨骼发育不良没有相似之处。此外,FLNA的核功能在Filamin A铰链-1缺失的情况下得以维持:我们得出的结论是,在小鼠的整个生命周期中,铰链-1对于丝胺A蛋白的功能是不可或缺的。
The hinge-1 domain of Flna is not necessary for diverse physiological functions in mice
Introduction
The filamins are cytoskeletal binding proteins that dynamically crosslink actin into orthogonal networks or bundle it into stress fibres. The domain structure of filamin proteins is very well characterised, with an N-terminal actin-binding region, followed by 24 immunoglobulin-like repeat units. The repeat domains are separated into distinct segments by two regions of low-complexity known as hinge-1 and hinge-2. The role of hinge-1 especially has been proposed to be essential for protein function as it provides flexibility to the otherwise rigid protein, and is a target for cleavage by calpain. Hinge-1 protects cells from otherwise destructive forces, and the products of calpain cleavage are involved in critical cellular signalling processes, such as survival during hypoxia. Pathogenic variants in FLNA encoding Filamin A, including those that remove the hinge-1 domain, cause a wide range of survivable developmental disorders. In contrast, complete loss of function of this gene is embryonic lethal in human and mouse.
Methods and Results
In this study, we show that removing filamin A hinge-1 from mouse (FlnaΔH1), while preserving its expression level leads to no obvious developmental phenotype. Detailed characterisation of the skeletons of FlnaΔH1 mice showed no skeletal phenotype reminiscent of that found in the FLNA-causing skeletal dysplasia. Furthermore, nuclear functions of FLNA are maintained with loss of Filamin A hinge-1.
Conclusion
We conclude that hinge-1 is dispensable for filamin A protein function during development over the murine lifespan.
期刊介绍:
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