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引用次数: 0
摘要
几十年来,真核生物基因激活子的激活结构域(ADs)一直是个谜,因为它们的序列短小、极易变化,在结构上往往是内在无序的,而且与不确定数量的靶标相互作用。由于普遍缺乏特异性,通过招募辅助激活子来发挥 AD 功能这一广为接受的机制变得越来越复杂。分子生物学核心的长期谜团要求我们从根本上重新思考既定的概念。在此,我们回顾了支持一种新型基因激活机理模型的实验证据,该模型基于 ADs 通过与基因启动子核小体的表面活性近似随机的相互作用发挥作用。这个新模型与最近利用高通量合成生物学和生物信息学分析方法(包括机器学习)获得的信息丰富的实验数据相一致。我们阐明了为什么传统的序列、结构和相互作用特异性生化原理无法解释激活结构域的功能。这一观点提供了与液-液相分离模型的联系,表明近随机相互作用是生化功能的基础,并可推广到其他细胞功能。
Activation domains (ADs) of eukaryotic gene activators remain enigmatic for decades as short, extremely variable sequences which often are intrinsically disordered in structure and interact with an uncertain number of targets. The general absence of specificity increasingly complicates the utilization of the widely accepted mechanism of AD function by recruitment of coactivators. The long-standing enigma at the heart of molecular biology demands a fundamental rethinking of established concepts. Here, we review the experimental evidence supporting a novel mechanistic model of gene activation, based on ADs functioning via surfactant-like near-stochastic interactions with gene promoter nucleosomes. This new model is consistent with recent information-rich experimental data obtained using high-throughput synthetic biology and bioinformatics analysis methods, including machine learning. We clarify why the conventional biochemical principle of specificity for sequence, structures, and interactions fails to explain activation domain function. This perspective provides connections to the liquid–liquid phase separation model, signifies near-stochastic interactions as fundamental for the biochemical function, and can be generalized to other cellular functions.
期刊介绍:
Journal of Molecular Biology (JMB) provides high quality, comprehensive and broad coverage in all areas of molecular biology. The journal publishes original scientific research papers that provide mechanistic and functional insights and report a significant advance to the field. The journal encourages the submission of multidisciplinary studies that use complementary experimental and computational approaches to address challenging biological questions.
Research areas include but are not limited to: Biomolecular interactions, signaling networks, systems biology; Cell cycle, cell growth, cell differentiation; Cell death, autophagy; Cell signaling and regulation; Chemical biology; Computational biology, in combination with experimental studies; DNA replication, repair, and recombination; Development, regenerative biology, mechanistic and functional studies of stem cells; Epigenetics, chromatin structure and function; Gene expression; Membrane processes, cell surface proteins and cell-cell interactions; Methodological advances, both experimental and theoretical, including databases; Microbiology, virology, and interactions with the host or environment; Microbiota mechanistic and functional studies; Nuclear organization; Post-translational modifications, proteomics; Processing and function of biologically important macromolecules and complexes; Molecular basis of disease; RNA processing, structure and functions of non-coding RNAs, transcription; Sorting, spatiotemporal organization, trafficking; Structural biology; Synthetic biology; Translation, protein folding, chaperones, protein degradation and quality control.
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