Daria V. Goliusova, Margarita Y. Sharikova, Kristina A. Lavrenteva, Olga S. Lebedeva, Lidia K. Muranova, Nikolai B. Gusev, Alexandra N. Bogomazova, Maria A. Lagarkova
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FLNC molecules with an impaired native structure could be eliminated by the BAG3-mediated chaperone-assisted selective autophagy. Mutations in the <i>FLNC</i> gene could be accompanied by the changes in FLNC interaction with its protein partners and could lead to formation of aggregates, which overload the autophagy and proteasome protein degradation systems, thus facilitating development of various pathological processes. Molecular mechanisms of the <i>FLNC</i>-associated congenital disorders, called filaminopathies, remain poorly understood. This review is devoted to analysis of the structure and mechanisms of filamin C function in muscle and heart cells in normal state and in the <i>FLNC</i>-associated pathologies. 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引用次数: 0
摘要
丝胶蛋白 C(Filamin C,FLNC)是高分子量蛋白家族中的一员,可与各种细胞的细胞骨架中的肌动蛋白丝结合。在人类基因组中,FLNC 由位于第 7 号染色体上的 FLNC 基因编码,主要在横纹骨骼肌和心肌细胞中表达。丝胶 C 参与肌节中细肌动蛋白丝三维网络的组织和稳定,并扮演着机械传感器的角色,将机械信号传递给不同的蛋白质靶标。在机械应力作用下,FLNC 会发生解折,从而增加其聚集的风险。BAG3 介导的伴侣辅助选择性自噬可消除原生结构受损的 FLNC 分子。FLNC基因突变可能伴随着FLNC与其蛋白伙伴相互作用的改变,并可能导致聚集体的形成,使自噬和蛋白酶体蛋白降解系统超载,从而促进各种病理过程的发展。人们对与FLNC相关的先天性疾病(即丝氨酸病)的分子机制仍然知之甚少。这篇综述专门分析正常状态下和 FLNC 相关病症中肌肉和心脏细胞中丝氨酸 C 的结构和功能机制。所提供的数据总结了分子、细胞和组织层面的研究成果,让我们勾勒出进一步研究丝卡胺病致病机制的可行途径。
Filamin C (FLNC) is a member of a high-molecular weight protein family, which bind actin filaments in the cytoskeleton of various cells. In human genome FLNC is encoded by the FLNC gene located on chromosome 7 and is expressed predominantly in striated skeletal and cardiac muscle cells. Filamin C is involved in organization and stabilization of thin actin filaments three-dimensional network in sarcomeres, and is supposed to play a role of mechanosensor transferring mechanical signals to different protein targets. Under mechanical stress FLNC can undergo unfolding that increases the risk of its aggregation. FLNC molecules with an impaired native structure could be eliminated by the BAG3-mediated chaperone-assisted selective autophagy. Mutations in the FLNC gene could be accompanied by the changes in FLNC interaction with its protein partners and could lead to formation of aggregates, which overload the autophagy and proteasome protein degradation systems, thus facilitating development of various pathological processes. Molecular mechanisms of the FLNC-associated congenital disorders, called filaminopathies, remain poorly understood. This review is devoted to analysis of the structure and mechanisms of filamin C function in muscle and heart cells in normal state and in the FLNC-associated pathologies. The presented data summarize the results of research at the molecular, cellular, and tissue levels and allow us to outline promising ways for further investigation of pathogenetic mechanisms in filaminopathies.
期刊介绍:
Biochemistry (Moscow) is the journal that includes research papers in all fields of biochemistry as well as biochemical aspects of molecular biology, bioorganic chemistry, microbiology, immunology, physiology, and biomedical sciences. Coverage also extends to new experimental methods in biochemistry, theoretical contributions of biochemical importance, reviews of contemporary biochemical topics, and mini-reviews (News in Biochemistry).
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