Research Progress in the Functions of Key Enzymes of Ubiquitination Modification in Plant Stress Responses

doi:10.13560/j.cnki.biotech.bull.1985.2023-1095

Abstract

Abstract:

Ubiquitination is one of post-translational modifications of plant proteins, which is involved in the regulation of plant growth, development and various stress responses by selective degradation of proteins. The reaction of ubiquitination modification is carried out by the synergistic action of three key enzymes. Ubiquitin molecules are activated by linking to thiol ester bonds of ubiquitin-activating enzymes, and the activated ubiquitin molecules form a complex with ubiquitin-conjugating enzymes, and finally bind to the target protein under the action of ubiquitin-ligase enzymes. With the development of proteomics sequencing technology, the research on ubiquitination modification has become more widespread and deeper. A large number of ubiquitination modified proteins and their modification sites have been identified, which is conducive to further understanding the regulatory mechanism of proteins and further analyzing the function of proteins. In this paper, we mainly introduced the reaction process of the ubiquitin-proteasome system, the structure, quantity and classification of key enzymes of ubiquitination modification, and focused on the functions of ubiquitin-activating enzymes, ubiquitin-binding enzymes and ubiquitin-ligases in plant response to abiotic and biotic stresses. Concurrently, we summarized the issues in studying functions of the key enzymes in plant ubiquitination modification, and discussed the crosstalk between ubiquitination and other modifications, which is of great significance for further research on ubiquitination modification in the field of plant responses to various environmental stresses.

Key words: ubiquitination modification, ubiquitin-activating enzyme, ubiquitin-conjugating enzyme, ubiquitin-ligase enzyme, abiotic stress, biotic stress

GUO Hui-yan, DONG Xue, AN Meng-nan, XIA Zi-hao, WU Yuan-hua. Research Progress in the Functions of Key Enzymes of Ubiquitination Modification in Plant Stress Responses[J]. Biotechnology Bulletin, 2024, 40(4): 1-11.

Figures/Tables 5

References 79

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E3的类型 E3 type	结构特征 Structural feature	与底物的结合方式 Binding mode
HECT	单亚基（具有HECT结构域）	先与被E2激活的泛素结合形成E3-泛素硫酯中间体，最后再将泛素转移到靶标蛋白上
RING	单亚基（具有RING结构域，在结构域核心具有与锌离子结合的保守半胱氨酸和组氨酸残基）	不与泛素结合，直接将泛素从E2-泛素复合体转移到底物上
U-box	单亚基（具有U-box结构域）	不与泛素结合，直接将泛素从E2-泛素复合体转移到底物上
CRL	多亚基（由Cullin蛋白、RING-box蛋白和底物募集蛋白组成）	RING-box蛋白与E2-泛素复合体识别结合，Cullin蛋白发挥支架作用

E3的类型 E3 type	结构特征 Structural feature	与底物的结合方式 Binding mode
HECT	单亚基（具有HECT结构域）	先与被E2激活的泛素结合形成E3-泛素硫酯中间体，最后再将泛素转移到靶标蛋白上
RING	单亚基（具有RING结构域，在结构域核心具有与锌离子结合的保守半胱氨酸和组氨酸残基）	不与泛素结合，直接将泛素从E2-泛素复合体转移到底物上
U-box	单亚基（具有U-box结构域）	不与泛素结合，直接将泛素从E2-泛素复合体转移到底物上
CRL	多亚基（由Cullin蛋白、RING-box蛋白和底物募集蛋白组成）	RING-box蛋白与E2-泛素复合体识别结合，Cullin蛋白发挥支架作用