Solution NMR Structure and NMR-based Molecular Backbone Dynamics of UbKEKS: A Ubiquitin Variant Encoded in the UBB4 Pseudogene with Emerging Specific and New Functions.

IF 2.1 3区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Biochemistry and Cell Biology Pub Date : 2025-10-02 DOI:10.1139/bcb-2025-0166

Patrick Delattre, Danny Létourneau, Anna Meller, Xavier Roucou, Francois-Michel Boisvert, Pierre Lavigne

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引用次数: 0

Abstract

Recently, proteomics analyses using databases of unannotated ORFs revealed that ubiquitin (Ub) variants can be encoded and expressed from pseudogenes. One such pseudogene, UBBP4, produces UbKEKS, which contains four substitutions (Q2K, K33E, Q49K, N60S) relative to canonical Ub. Unlike Ub, UbKEKS does not promote proteasomal degradation through K48 linkages and instead modifies a distinct set of proteins. To elucidate the structural basis of this divergence, we solved the NMR solution structure of UbKEKS and characterized its backbone dynamics by 15N-relaxation. While UbKEKS retains the overall helix-grip fold, we observed significant rearrangements and amplified motions in residues governing the Ub pincer mode, a conformational switch that determines whether UIMs engage the canonical I44 interface or the α1-β3 edge. Specifically, Q2K and K33E cooperate to enhance motions on both fast (ps-ns) and slow (µs-ms) timescales within α1, the β1-β2 loop, and β5-regions central to pincer mode regulation. In addition, Q49K, adjacent to I44, perturbs UIM recognition and likely interferes with K48 chain formation and binding to the proteasomal receptor S5a. Collectively, our findings identify structural and dynamical determinants that explain UbKEKS's distinct substrate profile and inability to target proteins for degradation.

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UbKEKS的溶液核磁共振结构和基于核磁共振的分子骨架动力学：UBB4伪基因编码的泛素变体，具有新兴的特异性和新功能。

最近，利用未注释orf数据库进行的蛋白质组学分析表明，泛素（Ub）变异可以由假基因编码和表达。其中一个假基因UBBP4产生UbKEKS，相对于典型的Ub，它包含四个取代（Q2K, K33E, Q49K, N60S）。与Ub不同，UbKEKS不通过K48键促进蛋白酶体降解，而是修饰一组独特的蛋白质。为了阐明这种发散的结构基础，我们求解了UbKEKS的核磁共振溶液结构，并用15n -弛豫表征了其主链动力学。虽然UbKEKS保留了整体的螺旋握柄褶皱，但我们观察到在控制Ub钳形模式的残基中存在显著的重排和放大的运动，Ub钳形模式是一种构象开关，决定了UIMs是参与规范I44界面还是α1-β3边缘。具体来说，Q2K和K33E协同增强α1、β1-β2环和β5区域在钳子模式调节中心的快速（ps-ns）和慢速（µs-ms）时间尺度上的运动。此外，与I44相邻的Q49K干扰了UIM识别，并可能干扰K48链的形成和与蛋白酶体受体S5a的结合。总的来说，我们的发现确定了解释UbKEKS不同底物特征和无法靶向蛋白质降解的结构和动力学决定因素。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Biochemistry and Cell Biology 生物-生化与分子生物学

CiteScore

6.30

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Published since 1929, Biochemistry and Cell Biology explores every aspect of general biochemistry and includes up-to-date coverage of experimental research into cellular and molecular biology in eukaryotes, as well as review articles on topics of current interest and notes contributed by recognized international experts. Special issues each year are dedicated to expanding new areas of research in biochemistry and cell biology.