Combining multi‐omics analysis to identify host‐targeted targets for the control of Brucella infection

Author:

Yu Jiuwang1,Yuan Hongwei2,Guo Jiarong1,Dong Zhiheng3,Li Sha3,Fu Quan4,Aode Bilige5,Baoyin Sachula6,Bao Lidao1ORCID,Wu Lan1

Affiliation:

1. TCM Hospital of Mongolian Medicine in Hohhot Hohhot China

2. Department of Pathology Affiliated Hospital of Inner Mongolia Medical University Hohhot China

3. Department of Pharmacy Affiliated Hospital of Inner Mongolia Medical University Hohhot China

4. Department of Laboratory Affiliated Hospital of Inner Mongolia Medical University Hohhot China

5. Department of Mongolian Medicine Inner Mongolia Xilin Gol League Mongolian Medical Hospital Xilinhaote China

6. Mongolia Medical School Inner Mongolia Medical University Hohhot China

Abstract

AbstractHuman infections caused by Brucella (called brucellosis) are among the most common zoonoses worldwide with an estimated 500,000 cases each year. Since chronic Brucella infections are extremely difficult to treat, there is an urgent need for more effective therapeutics. As a facultative intracellular bacterium, Brucella is strictly parasitic in the host cell. Here, we performed proteomic and transcriptomic and metabolomic analyses on Brucella infected patients, mice and cells that provided an extensive “map” of physiological changes in brucellosis patients and characterized the metabolic pathways essential to the response to infection, as well as the associated cellular response and molecular mechanisms. This is the first report utilizing multi‐omics analysis to investigate the global response of proteins and metabolites associated with Brucella infection, and the data can provide a comprehensive insight to understand the mechanism of Brucella infection. We demonstrated that Brucella increased nucleotide synthesis in the host, consistent with increased biomass requirement. We also identified IMPDH2, a key regulatory complex that controls nucleotide synthesis during Brucella infection. Pharmacological targeting of IMPDH2, the rate‐limiting enzyme in guanine nucleotide biosynthesis, efficiently inhibits B. abortus growth both in vitro and in vivo. Through screening a library of natural products, we identified oxymatrine, an alkaloid obtained primarily from Sophora roots, is a novel and selective IMPDH2 inhibitor. In further in vitro bacterial inhibition assays, oxymatrine effectively inhibited the growth of B. abortus, which was impaired by exogenous supplementation of guanosine, a salvage pathway of purine nucleotides. This moderately potent, structurally novel compound may provide clues for further design and development of efficient IMPDH2 inhibitors and also demonstrates the potential of natural compounds from plants against Brucella.

Funder

Natural Science Foundation of Inner Mongolia

Publisher

Wiley

Subject

Applied Microbiology and Biotechnology,Biochemistry,Bioengineering,Biotechnology

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