Identification of a phenyl ester covalent inhibitor of caseinolytic protease and analysis of the ClpP1P2 inhibition in mycobacteria

Genhui Xiao , Yumeng Cui , Liangliang Zhou , Chuya Niu , Bing Wang , Jinglan Wang , Shaoyang Zhou , Miaomiao Pan , Chi Kin Chan , Yan Xia , Lan Xu , Yu Lu , Shawn Chen

mLife ›› 2025, Vol. 4 ›› Issue (2) : 155 -168.

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mLife ›› 2025, Vol. 4 ›› Issue (2) : 155 -168. DOI: 10.1002/mlf2.12169
ORIGINAL RESEARCH

Identification of a phenyl ester covalent inhibitor of caseinolytic protease and analysis of the ClpP1P2 inhibition in mycobacteria

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Abstract

The caseinolytic protease complex ClpP1P2 is crucial for protein homeostasis in mycobacteria and stress response and virulence of the pathogens. Its role as a potential drug target for combating tuberculosis (TB) has just begun to be substantiated in drug discovery research. We conducted a biochemical screening targeting the ClpP1P2 using a library of compounds phenotypically active against Mycobacterium tuberculosis (Mtb). The screening identified a phenyl ester compound GDI-5755, inhibiting the growth of Mtb and M. bovis BCG, the model organism of mycobacteria. GDI-5755 covalently modified the active-site serine residue of ClpP1, rendering the peptidase inactive, which was delineated through protein mass spectrometry and kinetic analyses. GDI-5755 exerted antibacterial activity by inhibiting ClpP1P2 in the bacteria, which could be demonstrated through a minimum inhibitory concentration (MIC) shift assay with a clpP1 CRISPRi knockdown (clpP1-KD) mutant GH189. The knockdown also remarkably heightened the mutant's sensitivity to ethionamide and meropenem, but not to many other TB drugs. On the other hand, a comparative proteomic analysis of wild-type cells exposed to GDI-5755 revealed the dysregulated proteome, specifically showing changes in the expression levels of multiple TB drug targets, including EthA, LdtMt2, and PanD. Subsequent evaluation confirmed the synergistic activity of GDI-5755 when combined with the TB drugs to inhibit mycobacterial growth. Our findings indicate that small-molecule inhibitors targeting ClpP1P2, when used alongside existing TB medications, could represent novel therapeutic strategies.

Keywords

caseinolytic protease / chemical–genetic interaction / drug combination / enzyme inhibitor / mycobacteria

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Genhui Xiao, Yumeng Cui, Liangliang Zhou, Chuya Niu, Bing Wang, Jinglan Wang, Shaoyang Zhou, Miaomiao Pan, Chi Kin Chan, Yan Xia, Lan Xu, Yu Lu, Shawn Chen. Identification of a phenyl ester covalent inhibitor of caseinolytic protease and analysis of the ClpP1P2 inhibition in mycobacteria. mLife, 2025, 4(2): 155-168 DOI:10.1002/mlf2.12169

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2025 The Author(s). mLife published by John Wiley & Sons Australia, Ltd on behalf of Institute of Microbiology, Chinese Academy of Sciences.

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