Scalarane-Type Sesterterpenoids from the Marine Sponge Lendenfeldia sp. Alleviate Inflammation in Human Neutrophils.
Bo-Rong PengKuei-Hung LaiGene-Hsiang LeeSteve Sheng-Fa YuChang-Yih DuhJui-Hsin SuLi-Guo ZhengTsong-Long HwangPing-Jyun SungPublished in: Marine drugs (2021)
Sponge-derived scalaranes are remarkable sesterterpenoids previously found to exhibit profound inhibitory effects against neutrophilic inflammation. In our current work, we constructed the metabolomic profile of marine sponge Lendenfeldia sp. for the first time using a tandem mass spectrometry (MS/MS) molecular networking approach. The results highlighted the rich chemical diversity of these scalaranes, motivating us to conduct further research to discover novel scalaranes targeting neutrophilic inflammation. MS- and NMR-assisted isolation and elucidation led to the discovery of seven new homoscalaranes, lendenfeldaranes K-Q (1-7), characterized by methylation at C-24, together with five known derivatives, lendenfeldarane B (8), 25-nor-24-methyl-12,24-dioxoscalar-16-en-22-oic acid (9), 24-methyl-12,24,25-trioxoscalar-16-en-22-oic acid (10), felixin B (11), and 23-hydroxy-20-methyldeoxoscalarin (12). Scalaranes 1-4 and 6-12 were assayed against superoxide anion generation and elastase release, which represented the neutrophilic inflammatory responses of respiratory burst and degranulation, respectively. The results indicated that 1-3 and 6-12 exhibited potential anti-inflammatory activities (IC50 for superoxide anion scavenging: 0.87~6.57 μM; IC50 for elastase release: 1.12~6.97 μM).
Keyphrases
- tandem mass spectrometry
- oxidative stress
- ms ms
- ultra high performance liquid chromatography
- high performance liquid chromatography
- anti inflammatory
- liquid chromatography
- high resolution
- mass spectrometry
- endothelial cells
- simultaneous determination
- small molecule
- gas chromatography
- hydrogen peroxide
- multiple sclerosis
- intellectual disability
- solid phase extraction
- high throughput
- high frequency
- wastewater treatment
- cancer therapy
- nitric oxide
- single molecule
- single cell