Diabetic mellitus (DM) is a carbohydrate metabolic disorder that involves high blood sugar because insulin works abnormally. Type 2 diabetes accounts for most of them. However, diabetes treatments such as GLP-1 and DPP-4 inhibitors commonly caused side effects including gastrointestinal disorders. Grifola frondosa (G. frondosa) revealed various pharmacological effects in recent studies. It has a variety of anti-cancer polysaccharides through host-mediated mechanisms. D-fraction in G. frondosa has apoptotic effects, promoting myeloid cell proliferation and differentiation into granulocytes-macrophages. It has also been shown to reduce the survival rate of breast cancer cells. Though, no further study has been conducted on the specific effects of G. frondosa in the db/db mouse. Therefore, we would like to research the blood glucose improving effect of G. frondosa, a natural material, in type 2 diabetes model mouse, in this study. G. frondosa was administered to the disease model mouse (BKS.Cg-+Leprdb/+Leprdb/OlaHsd) for 8 weeks to monitor weight and blood glucose changes every week. And we evaluated anti-diabetes effects by checking biomarker changes shown through blood. Experiment did not show statistically significant weight differences, but control groups showed significantly higher weight gain than G. frondosa administered groups. We collected blood from the tail veins of the db/db mouse each week. As a result, the lowest blood sugar level was shown in the 500 mg/ kg group of G. frondosa. Glucose in the blood was examined with HBA1c, and 7.8% was shown in the 500 mg/kg administration group, lower than in other groups. These results suggest the potential improvements of diabetes in G. frondosa.

Insulin/IGF signaling (IIS) regulates multiple physiological processes such as larval growth, reproduction, and life span in many organisms including legume pod borer, Maruca vitrata (Lepidoptera: Crambidae). RNA interference of IIS components, insulin receptor (InR) and Forkhead Box O (FOXO), impaired larval growth and female reproduction. To further validate the physiological roles of InR and FOXO, we generated knock-out (KO) mutants using CRISPR/Cas9-mediated genome-editing technology. Both KO mutants exhibited delayed larval growth and reduced pupal and adult body sizes. In conclusion, these results demonstrated the critical role of insulin signaling (IIS) pathway to control M. vitrata growth and development.

Insect growth depends on temperature and nutrient. Intake nutrients activate insulin signaling pathway, which mediatesthe nutrient signal to coordinate growth in entire body. A subtropical species, Maruca vitrata (Lepidoptera: Crambidae),gives serious damages on various Fabaceae crops. This study predicted seven components (InR, IRS, PI3K, PTEN, Akt,mTOR, FOXO) of the insulin signal and showed that some of the insulin gene expression levels are highly correlatedwith developmental rates. These correlations may be applied to amend a temperature-dependent growth modeling of M.vitrata.

Colony collapse disorder (CCD), a phenomenon of honeybees disappearance, has been reported since 2006. Chronic exposure to neonicotinoid insecticides, particularly imidacloprid, has been suggested to impair forager’s ability for foraging and be a main cause of CCD. Recently, it has been reported that imidacloprid induces insulin resistance in animal cell line by blocking glucose uptake. Similarly to human insulin, insulin-like peptide (ILP) of insects is involved in maintaining blood glucose contents in hemolymph by regulating the concentration of trehalose and glycogen. Therefore, we have hypothesized that sublethal concentration of neonicotinoid may affect the metabolic pathway of honey bees as well. We investigated the transcription levels of the genes involved in the insulin/insulin-like signaling (IIS) pathway, such as AmILP and AmInR, following an acute or a chronic dietary exposure of sublethal concentrations of imidacloprid to foragers. In both experiments, honeybees showed increased expression levels of ILP and InR in a dose-dependent manner. Our results suggest that sublethal dose of imidacloprid likely upregulates IIS pathway, thereby rendering honey bees to become resistant to insulin.