The present study was designed to investigate the therapeutic effcts of Moutan Cortex(CM,root bark of Paeonia suffruticosa Andr) and Paeoniae Radix Rubra(PR,root of Paeonia veitchii Lynch) on metabolic disorders,focusing on the infuence of CM and PR on the obesity-related gut microbiota homeostasis.The diet-induced obese(DIO) mouse model was used to test the therapeutic effects of CM and PR.The mice were orally administered with CM and PR for 6 weeks,and oral glucose tolerance test(OGTT) and insulin tolerance test(ITT) were performed to evaluate the insulin sensitivity of the mice.Sterol-regulatory element binding proteins(SREBPs) and their target genes were measured by quantitative RT-PCR.High-throughput 16 S ribosomal RNA(16S rR NA) gene sequencing technology was used to determine the composition of gut microbiota,and the metabolites in serum were analyzed by GC-MS.Our results indicated that CM and PR combination alleviated obese and insulin resistance in the DIO mice,leading to increased glucose uptake and gene expression in muscle and liver,and down-regulated SREBPs and their target genes in liver.Interesting,neither the CM-PR extracts,nor the major components of CM and PR did not affect SREBPs activity in cultured cells.Meanwhile,CM and PR significantly modulated the gut microbiota of the high-fat diet(HFD) treated mice,similar to metformin,and CM-PR reversed the overall microbiota composition similar to the normal chow diet(NCD) treated mice.In conclusion,our results provide novel mechanisms of action for the effects of CM and PR in treating DIO-induced dysregulation of sugar and lipid metabolism.
AIM: To profile the chemical constituents in Jinqi Jiangtang tablets. METHOD: Based on the chromatographic retention behavior, fragmentation patterns of chemical components, and published lit- eratures, a high-performance liquid chromatography coupled with electrospray ionization quadrnpole time-of-flight tandem mass spectrometry (HPLC-ESI-Q-TOF/MS) method was established to characterize and identify components in Jinqi Jiangtang tablets. RESULTS: A total of 52 chemical compounds, including eight iridoid glycosides, seven phenolic acids, twelve alkaloids, six fla- vonoids, and nineteen saponins, were identified in Jinqi Jiangtang tablets. CONCLUSION: The established method could serve as a powerful tool for structural characterization and quality control of this Chinese herbal preparation.
SUN ShiXIE Zhi-ShenLIU E-HuYAN Yu-TingXU Xiao-JunLI Ping
As a culinary and medicinal herb, rosemary is widely used. The present work aimed to investigate the effects of rosemary extracts on metabolic diseases and the underlying mechanisms of action. Liver cells stably expressing SREBP reporter were used to evaluate the inhibitory effects of different fractions of rosemary extracts on SREBP activity. The obese mice induced by Western-type diet were orally administered with rosemary extracts or vehicle for 7 weeks, the plasma and tissue lipids were analyzed. SREBPs and their target genes were measured by quantitative RT-PCR. We demonstrated that the petroleum ether sub-fraction of rosemary extracts(PER) exhibited the best activity in regulating lipid metabolism by inhibiting SREBPs, while water and n-Bu OH sub-fraction showed the SREBPs agonist-effect. After PER treatment, there was a significant reduction of total SREBPs in liver cells. PER not only decreased SREBPs nuclear abundance, but also inhibited their activity, resulting in decreased expression of SREBP-1c and SREBP-2 target genes in vitro and in vivo. Inhibiting SREBPs by PER decreased the total triglycerides and cholesterol contents of the liver cells. In the mice fed with Western-type diet, PER treatment decreased TG, TC, ALT, glucose, and insulin in blood, and improved glucose tolerance and insulin sensitivity. Furthermore, PER treatment also decreased lipid contents in liver, brown adipose tissue, and white adipose tissue. Our results from the present study suggested that petroleum ether fraction of rosemary extracts exhibited the best potential of improving lipid metabolism by inhibiting SREBPs activity.
