Unveiling the Complexity of cis-Regulation Mechanisms in Kinases: A Comprehensive Analysis.

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-10-04 DOI:10.1002/prot.26751
Alvaro M Navarro, Macarena Alonso, Elizabeth Martínez-Pérez, Tamas Lazar, Toby J Gibson, Javier A Iserte, Peter Tompa, Cristina Marino-Buslje
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Abstract

Protein cis-regulatory elements (CREs) are regions that modulate the activity of a protein through intramolecular interactions. Kinases, pivotal enzymes in numerous biological processes, often undergo regulatory control via inhibitory interactions in cis. This study delves into the mechanisms of cis regulation in kinases mediated by CREs, employing a combined structural and sequence analysis. To accomplish this, we curated an extensive dataset of kinases featuring annotated CREs, organized into homolog families through multiple sequence alignments. Key molecular attributes, including disorder and secondary structure content, active and ATP-binding sites, post-translational modifications, and disease-associated mutations, were systematically mapped onto all sequences. Additionally, we explored the potential for conformational changes between active and inactive states. Finally, we explored the presence of these kinases within membraneless organelles and elucidated their functional roles therein. CREs display a continuum of structures, ranging from short disordered stretches to fully folded domains. The adaptability demonstrated by CREs in achieving the common goal of kinase inhibition spans from direct autoinhibitory interaction with the active site within the kinase domain, to CREs binding to an alternative site, inducing allosteric regulation revealing distinct types of inhibitory mechanisms, which we exemplify by archetypical representative systems. While this study provides a systematic approach to comprehend kinase CREs, further experimental investigations are imperative to unravel the complexity within distinct kinase families. The insights gleaned from this research lay the foundation for future studies aiming to decipher the molecular basis of kinase dysregulation, and explore potential therapeutic interventions.

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揭示激酶顺式调节机制的复杂性:全面分析。
蛋白质顺式调节元件(CRE)是通过分子内相互作用调节蛋白质活性的区域。激酶是众多生物过程中的关键酶,通常通过顺式的抑制性相互作用进行调控。本研究采用结构和序列分析相结合的方法,深入研究了 CREs 介导的激酶顺式调控机制。为此,我们通过多序列比对,将具有注释 CREs 的激酶整理成同源物家族,建立了一个广泛的数据集。关键的分子属性,包括紊乱和二级结构含量、活性和 ATP 结合位点、翻译后修饰和疾病相关突变,都被系统地映射到所有序列上。此外,我们还探索了活性和非活性状态之间构象变化的可能性。最后,我们探索了这些激酶在无膜细胞器中的存在,并阐明了它们在其中的功能作用。CRE显示出连续的结构,从短的无序绵延到完全折叠的结构域。CREs 在实现抑制激酶这一共同目标方面所表现出的适应性包括与激酶结构域内活性位点的直接自身抑制作用,以及 CREs 与替代位点的结合,从而诱导异位调节,揭示了不同类型的抑制机制,我们通过典型的代表系统对此进行了例证。虽然这项研究为理解激酶 CRE 提供了一种系统方法,但要揭示不同激酶家族内部的复杂性,进一步的实验研究势在必行。从这项研究中获得的启示为今后的研究奠定了基础,这些研究旨在破译激酶失调的分子基础,并探索潜在的治疗干预措施。
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CiteScore
7.20
自引率
4.30%
发文量
567
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