MAGI-1的神奇之处：一种具有多信号体和功能可塑性的支架蛋白。

IF 2.4 4区生物学 Q4 CELL BIOLOGY

Biology of the Cell Pub Date : 2022-04-07 DOI:10.1111/boc.202200014

Katherine J. D. A. Excoffon, Christina L. Avila, Mahmoud S. Alghamri, Abimbola O. Kolawole

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引用次数: 2

摘要

MAGI-1是一种重要的细胞支架蛋白，具有110多种不同的细胞和微生物蛋白相互作用因子。自1997年发现MAGI-1以来，MAGI-1与多种细胞功能有关，如极性、细胞间通讯、神经过程、肾功能以及包括癌症和微生物感染在内的多种疾病。此外，由于发现了额外的PDZ结构域，MAGI-1的命名发生了变化，导致文献缺乏连续性。我们讨论了MAGI-1的命名，并总结了已知相互作用的许多关键功能。鉴于许多相互作用因子的重要性，如人乳头瘤病毒E6、柯萨奇病毒和腺病毒受体（CAR）以及PTEN，基于MAGI的相互作用的增强或破坏有可能影响细胞功能，这些功能可能被用作多种疾病的治疗策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

The magic of MAGI-1: A scaffolding protein with multi signalosomes and functional plasticity

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The magic of MAGI-1: A scaffolding protein with multi signalosomes and functional plasticity

MAGI-1 is a critical cellular scaffolding protein with over 110 different cellular and microbial protein interactors. Since the discovery of MAGI-1 in 1997, MAGI-1 has been implicated in diverse cellular functions such as polarity, cell–cell communication, neurological processes, kidney function, and a host of diseases including cancer and microbial infection. Additionally, MAGI-1 has undergone nomenclature changes in response to the discovery of an additional PDZ domain, leading to lack of continuity in the literature. We address the nomenclature of MAGI-1 as well as summarize many of the critical functions of the known interactions. Given the importance of many of the interactors, such as human papillomavirus E6, the Coxsackievirus and adenovirus receptor (CAR), and PTEN, the enhancement or disruption of MAGI-based interactions has the potential to affect cellular functions that can potentially be harnessed as a therapeutic strategy for a variety of diseases.

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来源期刊

Biology of the Cell 生物-细胞生物学

CiteScore

5.30

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： The journal publishes original research articles and reviews on all aspects of cellular, molecular and structural biology, developmental biology, cell physiology and evolution. It will publish articles or reviews contributing to the understanding of the elementary biochemical and biophysical principles of live matter organization from the molecular, cellular and tissues scales and organisms. This includes contributions directed towards understanding biochemical and biophysical mechanisms, structure-function relationships with respect to basic cell and tissue functions, development, development/evolution relationship, morphogenesis, stem cell biology, cell biology of disease, plant cell biology, as well as contributions directed toward understanding integrated processes at the organelles, cell and tissue levels. Contributions using approaches such as high resolution imaging, live imaging, quantitative cell biology and integrated biology; as well as those using innovative genetic and epigenetic technologies, ex-vivo tissue engineering, cellular, tissue and integrated functional analysis, and quantitative biology and modeling to demonstrate original biological principles are encouraged.