Anti-inflammatory effect and antihepatoma mechanism of carrimycin

Xiu-Yan Li; Yu-Ting Luo; Yan-Hong Wang; Zhi-Xin Yang; Yu-Zhou Shang; Qing-Xia Guan

doi:10.3748/wjg.v29.i14.2134

Anti-inflammatory effect and antihepatoma mechanism of carrimycin

World J Gastroenterol. 2023 Apr 14;29(14):2134-2152. doi: 10.3748/wjg.v29.i14.2134.

Authors

Xiu-Yan Li¹, Yu-Ting Luo¹, Yan-Hong Wang¹, Zhi-Xin Yang¹, Yu-Zhou Shang¹, Qing-Xia Guan²

Affiliations

¹ Key Laboratory of Basic and Application Research of Beiyao, Heilongjiang University of Chinese Medicine, Harbin 150040, Heilongjiang Province, China.
² Key Laboratory of Basic and Application Research of Beiyao, Heilongjiang University of Chinese Medicine, Harbin 150040, Heilongjiang Province, China. 546105832@qq.com.

Abstract

Background: New drugs are urgently needed for the treatment of liver cancer, a feat that could be feasibly accomplished by finding new therapeutic purposes for marketed drugs to save time and costs. As a new class of national anti-infective drugs, carrimycin (CAM) has strong activity against gram-positive bacteria and no cross resistance with similar drugs. Studies have shown that the components of CAM have anticancer effects.

Aim: To obtain a deeper understanding of CAM, its distribution, metabolism and anti-inflammatory effects were assessed in the organs of mice, and its mechanism of action against liver cancer was predicted by a network pharmacology method.

Methods: In this paper, the content of isovaleryl spiramycin III was used as an index to assess the distribution and metabolism of CAM and its effect on inflammatory factors in various mouse tissues and organs. Reverse molecular docking technology was utilized to determine the target of CAM, identify each target protein based on disease type, and establish a target protein-disease type network to ascertain the effect of CAM in liver cancer. Then, the key action targets of CAM in liver cancer were screened by a network pharmacology method, and the core targets were verified by molecular docking and visual analyses.

Results: The maximum CAM concentration was reached in the liver, kidney, lung and spleen 2.5 h after intragastric administration. In the intestine, the maximum drug concentration was reached 0.5 h after administration. In addition, CAM significantly reduced the interleukin-4 (IL-4) levels in the lung and kidney and especially the liver and spleen; moreover, CAM significantly reduced the IL-1β levels in the spleen, liver, and kidney and particularly the small intestine and lung. CAM is predicted to regulate related pathways by acting on many targets, such as albumin, estrogen receptor 1, epidermal growth factor receptor and caspase 3, to treat cancer, inflammation and other diseases.

Conclusion: We determined that CAM inhibited inflammation. We also predicted the complex multitargeted effects of CAM that involve multiple pathways and the diversity of these effects in the treatment of liver cancer, which provides a basis and direction for further clinical research.

Keywords: Anti-hepatoma; Anti-inflammatory; Carrimycin; Liver cancer; Network pharmacology; Reverse molecular docking.

MeSH terms

Animals
Anti-Inflammatory Agents / pharmacology
Anti-Inflammatory Agents / therapeutic use
Drugs, Chinese Herbal*
Inflammation / drug therapy
Liver Neoplasms* / drug therapy
Mice
Molecular Docking Simulation

Substances

carrimycin
Anti-Inflammatory Agents
Drugs, Chinese Herbal