Jie Li1,2,3, Yu-Jun Tan1,2,3, Ming-Zhi Wang1,2,3, Ying Sun1,2,3, Guang-Yan Li1,3, Qi-Long Wang1,2,3, Jing-Chun Yao1,2,3, Jiang Yue4, Zhong Liu1,3,5, Gui-Min Zhang1,3, Yu-Shan Ren1,3. 1. Shandong New Time Pharmaceutical Co., Ltd., Lunan Pharmaceutical Group Co., Ltd., Linyi, China. 2. Center for New Drug Safety Evaluation of Lunan Pharmaceutical, Lunan Pharmaceutical Group Co., Ltd., Linyi, China. 3. State Key Laboratory of Generic Manufacture Technology of Chinese Traditional Medicine, Lunan Pharmaceutical Group Co., Ltd., Linyi, China. 4. Department of Pharmacology, Wuhan University School of Basic Medical Sciences, Wuhan, China. 5. National Engineering and Technology Research Center of Chirality Pharmaceutical, Lunan Pharmaceutical Group Co., Ltd., Linyi, China.
Abstract
BACKGROUND AND PURPOSE: Acute kidney injury (AKI) is a rapid renal dysfunctional disease, for which no effective drugs or therapies are available to improve prognosis. Loganetin is a natural product with unknown bioactivities. Here, we identified a new protective effect and mechanism of Loganetin in a mouse model of AKI induced by rhabdomyolysis. EXPERIMENTAL APPROACH: AKI was induced using glycerol by i.m. injection in mice models. Thirty minutes and 24 and 48 hr after injection of glycerol, the mice received 2 and 18 mg·kg-1 of Loganetin i.p. respectively. Then mice blood and kidney were collected for various biochemical and histopathological studies. Mechanistic studies on modulation of AKI by Loganetin were performed using HK-2 cells and Toll-like receptor 4 (TLR4) knockout mice. KEY RESULTS: In the Loganetin treated group, kidney damage and mortality rate were declined, and blood urea nitrogen and serum creatinine were much lower. Loganetin prevented damage to the tubular structures induced by glycerol and decreased apoptotic cells at the corticomedullary junction. In HK-2 cells, Loganetin could inhibit NF-κB pathway and pro-apoptotic genes expression. However, TLR4 was silenced by a specific shRNA, and the inhibitory effect of Loganetin in HK-2 cells vanished. Loganetin also down-regulated the expression of inflammation factors by suppressing TLR4 activity. CONCLUSION AND IMPLICATIONS: All the results suggested that TLR4 plays a critical role in AKI development, and Loganetin ameliorates AKI by inhibiting TLR4 activity and blocking the JNK/p38 pathway, which provides a new strategy for AKI treatment.
BACKGROUND AND PURPOSE:Acute kidney injury (AKI) is a rapid renal dysfunctional disease, for which no effective drugs or therapies are available to improve prognosis. Loganetin is a natural product with unknown bioactivities. Here, we identified a new protective effect and mechanism of Loganetin in a mouse model of AKI induced by rhabdomyolysis. EXPERIMENTAL APPROACH: AKI was induced using glycerol by i.m. injection in mice models. Thirty minutes and 24 and 48 hr after injection of glycerol, the mice received 2 and 18 mg·kg-1 of Loganetin i.p. respectively. Then mice blood and kidney were collected for various biochemical and histopathological studies. Mechanistic studies on modulation of AKI by Loganetin were performed using HK-2 cells and Toll-like receptor 4 (TLR4) knockout mice. KEY RESULTS: In the Loganetin treated group, kidney damage and mortality rate were declined, and blood ureanitrogen and serum creatinine were much lower. Loganetin prevented damage to the tubular structures induced by glycerol and decreased apoptotic cells at the corticomedullary junction. In HK-2 cells, Loganetin could inhibit NF-κB pathway and pro-apoptotic genes expression. However, TLR4 was silenced by a specific shRNA, and the inhibitory effect of Loganetin in HK-2 cells vanished. Loganetin also down-regulated the expression of inflammation factors by suppressing TLR4 activity. CONCLUSION AND IMPLICATIONS: All the results suggested that TLR4 plays a critical role in AKI development, and Loganetin ameliorates AKI by inhibiting TLR4 activity and blocking the JNK/p38 pathway, which provides a new strategy for AKI treatment.
Authors: Tarek M El-Achkar; Xiaoping Huang; Zoya Plotkin; Ruben M Sandoval; Georges J Rhodes; Pierre C Dagher Journal: Am J Physiol Renal Physiol Date: 2005-12-06
Authors: Hanning You; Ting Gao; Wesley M Raup-Konsavage; Timothy K Cooper; Sarah K Bronson; W Brian Reeves; Alaa S Awad Journal: Kidney Int Date: 2016-12-01 Impact factor: 10.612
Authors: Ki Yong Lee; Sang Hyun Sung; Seung Hyun Kim; Young Pyo Jang; Tae Hwan Oh; Young Choong Kim Journal: Arch Pharm Res Date: 2009-05-27 Impact factor: 4.946
Authors: Karel Miettinen; Lemeng Dong; Nicolas Navrot; Thomas Schneider; Vincent Burlat; Jacob Pollier; Lotte Woittiez; Sander van der Krol; Raphaël Lugan; Tina Ilc; Robert Verpoorte; Kirsi-Marja Oksman-Caldentey; Enrico Martinoia; Harro Bouwmeester; Alain Goossens; Johan Memelink; Danièle Werck-Reichhart Journal: Nat Commun Date: 2014-04-07 Impact factor: 14.919
Authors: A T Press; M J Butans; T P Haider; C Weber; S Neugebauer; M Kiehntopf; U S Schubert; M G Clemens; M Bauer; A Kortgen Journal: Sci Rep Date: 2017-11-13 Impact factor: 4.379
Authors: Rongshuang Huang; Min Shi; Fan Guo; Yuying Feng; Yanhuan Feng; Jing Liu; Lingzhi Li; Yan Liang; Jin Xiang; Song Lei; Liang Ma; Ping Fu Journal: Front Pharmacol Date: 2018-08-08 Impact factor: 5.810
Authors: Cristina Vázquez-Carballo; Melania Guerrero-Hue; Cristina García-Caballero; Sandra Rayego-Mateos; Lucas Opazo-Ríos; José Luis Morgado-Pascual; Carmen Herencia-Bellido; Mercedes Vallejo-Mudarra; Isabel Cortegano; María Luisa Gaspar; Belén de Andrés; Jesús Egido; Juan Antonio Moreno Journal: Int J Mol Sci Date: 2021-01-15 Impact factor: 5.923