Anti-thrombosis effect of diosgenyl saponins in vitro and in vivo

Thrombosis in coronary or cerebral arteries is the major cause of morbidity and mortality worldwide. Diosgenin and total steroidal saponins extracted from the rhizome of Dioscorea zingiberensis C.H. Wright are demonstrated to have anti-thrombotic activity. However, few studies describe the anti-thrombotic activity of the diosgenyl saponin monomer. In the present study, a simple and convenient method for the preparation of a new disaccharide saponin, diosgenyl β-d-galactopyranosyl-(1 → 4)-β-d-glucopyranoside (3), is described. We evaluated the anti-thrombotic effects of diosgenin and four diosgenyl saponins by measuring the bleeding time; the results showed that compound 3 exhibits outstanding efficiency in prolonging the bleeding time. Furthermore, we assessed whether compound 3 could alter platelet aggregation in vitro and in vivo. In addition, activated partial thromboplastin time (APTT), thrombin time (TT), prothrombin time (PT), coagulation factors and protection rate in mice were measured to evaluate the anti-thrombotic effect of compound 3. The results show that compound 3 inhibited platelet aggregation, prolonged APTT, inhibited factor VIII activities in rats, and increased the protection rate in mice in a dose-dependent manner. Taken together, these findings suggested that diosgenyl saponins, especially compound 3, had anti-thrombotic activity. It may execute anti-thrombotic activity through inhibiting factor VIII activities and platelet aggregation.     

Effect of Amino Acids on Lysosomal Proteolytic Activities in Rat Livers

(R)-2-(4′-Isobutylphenyl)propanoic acid (ibuprofen), (S)-3(4′-isobutylphenyl)butanoic acid and (S)-4-(4′-isobutylphenyl)pentanoic acid were obtained using microbial oxidation of (±)-l-isobutyl-4-(1′ -methyloctyl)benzene by Rhodococcus sp. BPM 1613.     

Extract from Acanthopanax senticosus Harms (Siberian Ginseng) Activates NTS and SON/PVN in the Rat Brain

The extract of the stem bark of Siberian ginseng, Acanthopanax senticosus Harms (ASH), is believed to play a body-coping role in stress through a brain noradrenergic mechanism. The present study was carried out to investigate the effect of ASH on the neuronal activation patterns of c-Fos expression in the rat brain. With ASH administration, c-Fos accumulated in both the supraoptic nuclei (SON) and paraventricular nuclei (PVN), which regulate stress response. Only the caudal regions in the nucleus of the solitary tract (NTS), a locus innervating both the SON and PVN, were activated. Such a neuro-anatomical pattern associated with ASH suggests the possible involvement of these stress-related brain loci.     

Effects of Korean Red Ginseng extract on hepatic lipid accumulation in HepG2 cells

In this study, we investigated the effects of Korean red ginseng water extract (KRGE) on hepatic lipid accumulation in HepG2 cells. KRGE decreased hepatic triglyceride and cholesterol levels. Further, KRGE suppressed expression of fatty acid synthase (FAS) and 3-hydroxy-3-methyl glutaryl coenzyme A (HMG-CoA) reductase. These results suggest that KRGE may reduce hepatic lipid accumulation by inhibition of FAS and HMG-CoA reductase expression in HepG2 cells.     

重楼皂苷VII对SW-480 细胞凋亡和周期的影响及机制研究

目的：探讨重楼皂苷VII (Paris saponin VII, PSVII) 对人结肠癌SW480 细胞凋亡和周期的影响及其机制。方法：采用Cell Counting Kit-8（CCk-8）试剂盒方法观察PSVII 对SW-480 细胞增殖的影响;流失细胞术研究PSVII对SW480细胞凋亡和周期的 作用;培养SW-480 细胞并给予1.0 umol/L、2.0 umol/L 和4.0 umol/L PSVII 24 h后,采用Western blot 法检测凋亡相关蛋白 Caspase-3、Caspase-8、Caspase-9、Bax和Bcl-2 及周期相关蛋白Cdk-4、Cdk-6、CyclinD1 和p21 的表达变化。结果：PSVII可明显抑 制SW-480 细胞增殖,并诱导其凋亡,其IC50值为5.25± 0.46 umol/L;PSVII 可促进SW-480 细胞Caspase-3、Caspase-8、Caspase-9、 Bax及p21 的表达,降低Bcl-2、Cdk-4、Cdk-6和CyclinD1 的表达。结论：PSVII可以通过线粒体和死亡受体途径诱导SW-480 细胞 凋亡;将SW-480 细胞周期阻滞于G1 期是通过上调p21,抑制Cdk-4、Cdk-6 与Cyclin D1 周期调控蛋白的表达。     

Killing cancer with platycodin D through multiple mechanisms

Cancer is a multi‐faceted disease comprised of a combination of genetic, epigenetic, metabolic and signalling aberrations which severely disrupt the normal homoeostasis of cell growth and death. Rational developments of highly selective drugs which specifically block only one of the signalling pathways have been associated with limited therapeutic success. Multi‐targeted prevention of cancer has emerged as a new paradigm for effective anti‐cancer treatment. Platycodin D, a triterpenoid saponin, is one the major active components of the roots of Platycodon grandiflorum and possesses multiple biological and pharmacological properties including, anti‐nociceptive, anti‐atherosclerosis, antiviral, anti‐inflammatory, anti‐obesity, immunoregulatory, hepatoprotective and anti‐tumour activities. Recently, the anti‐cancer activity of platycodin D has been extensively studied. The purpose of this review was to give our perspectives on the current status of platycodin D and discuss its anti‐cancer activity and molecular mechanisms which may help the further design and conduct of pre‐clinical and clinical trials to develop it successfully into a potential lead drug for oncological therapy. Platycodin D has been shown to fight cancer by inducing apoptosis, cell cycle arrest, and autophagy and inhibiting angiogenesis, invasion and metastasis by targeting multiple signalling pathways which are frequently deregulated in cancers suggesting that this multi‐target activity rather than a single effect may play an important role in developing platycodin D into potential anti‐cancer drug.     

Enzymatic transglycosylation of ginsenoside Rg1 by rice seed α-glucosidase

Six α-monoglucosyl derivatives of ginsenoside Rg1 (G-Rg1) were synthesized by transglycosylation reaction of rice seed α-glucosidase in the reaction mixture containing maltose as a glucosyl donor and G-Rg1 as an acceptor. Their chemical structures were identified by spectroscopic analysis, and the effects of reaction time, pH, and glycosyl donors on transglycosylation reaction were investigated. The results showed that rice seed α-glucosidase transfers α-glucosyl group from maltose to G-Rg1 by forming either α-1,3 (α-nigerosyl)-, α-1,4 (α-maltosyl)-, or α-1,6 (α-isomaltosyl)-glucosidic linkages in β-glucose moieties linked at the C6- and C20-position of protopanaxatriol (PPT)-type aglycone. The optimum pH range for the transglycosylation reaction was between 5.0 and 6.0. Rice seed α-glucosidase acted on maltose, soluble starch, and PNP α-D-glucopyranoside as glycosyl donors, but not on glucose, sucrose, or trehalose. These α-monoglucosyl derivatives of G-Rg1 were easily hydrolyzed to G-Rg1 by rat small intestinal and liver α-glucosidase in vitro.