Enhanced liver but not muscle OXPHOS in diabetes and reduced glucose output by complex I inhibition.

Mitochondrial function is critical in energy metabolism. To fully capture how the mitochondrial function changes in metabolic disorders, we investigated mitochondrial function in liver and muscle of animal models mimicking different types and stages of diabetes. Type 1 diabetic mice were induced by streptozotocin (STZ) injection. The db/db mice were used as type 2 diabetic model. High-fat diet-induced obese mice represented pre-diabetic stage of type 2 diabetes. Oxidative phosphorylation (OXPHOS) of isolated mitochondria was measured with Clark-type oxygen electrode. Both in early and late stages of type 1 diabetes, liver mitochondrial OXPHOS increased markedly with complex IV-dependent OXPHOS being the most prominent. However, ATP, ADP and AMP contents in the tissue did not change. In pre-diabetes and early stage of type 2 diabetes, liver mitochondrial complex I and II-dependent OXPHOS increased greatly then declined to almost normal at late stage of type 2 diabetes, among which alteration of complex I-dependent OXPHOS was the most significant. In contrast, muscle mitochondrial OXPHOS in HFD, early-stage type 1 and 2 diabetic mice, did not change. In vitro, among inhibitors to each complex, only complex I inhibitor rotenone decreased glucose output in primary hepatocytes without cytotoxicity both in the absence and presence of oleic acid (OA). Rotenone affected cellular energy state and had no effects on cellular and mitochondrial reactive oxygen species production. Taken together, the mitochondrial OXPHOS of liver but not muscle increased in obesity and diabetes, and only complex I inhibition may ameliorate hyperglycaemia via lowering hepatic glucose production.

Panaxynol protects cortical neurons from ischemia-like injury by up-regulation of HIF-1alpha expression and inhibition of apoptotic cascade.

Apoptosis is one of the major characteristics of delayed neuronal degeneration in neuronal injury following cerebral ischemia. Hypoxia-induced apoptosis may be co-regulated by HIF-1alpha as well as many other factors. In recent years, numerous studies concerning panaxynol (PNN) have been reported. However, whether PNN can show anti-hypoxia properties is still unknown. In this study, the protective effects of PNN on OGD-induced neuronal apoptosis and potential mechanisms were investigated. Pretreatment of the cells with PNN for 24h following exposure to OGD resulted in a significant elevation of cell survival determined by MTT assay, LDH assay, Hoechst staining and flow cytometric assessment. In addition to enhancing the expression of HIF-1alpha, PNN also normalized the caspase-3 expression/activation and increased the Bcl-2/Bax ratio. In our study, the increased level of HIF-1alpha with decreased cellular apoptosis suggested an important role for HIF-1alpha in hypoxic neurons. These results indicated that the neuroprotective effects of PNN on hypoxic neurons were at least partly due to up-regulation of HIF-1alpha and raised the possibility that PNN might reduce neurodegenerative disorders and ischemic brain diseases.

Cytotoxic phenylpropanoids from carrot.

Carrot is widely used as a foodstuff. The active components such as beta-carotene and panaxynol have been studied by many researchers. In this investigation of nonpolar active components from carrot, a new phenylpropanoid, epilaserine oxide ( 3), was isolated along with six known compounds, laserine ( 1), 2-epilaserine ( 2), panaxynol ( 4), ginsenoyne K ( 5), (8 E)-1,8-heptadecadiene-4,6-diyne-3,10-diol ( 6), and vaginatin ( 7). Their structures were deduced on the basis of spectroscopic methods. Significant cytotoxicity of 2-epilaserine against HL-60 cells was observed, which implied that phenylpropanoids were cytotoxic compounds in carrot. Laserine and 2-epilaserine in carrots from diverse locations in China were quantified by HPLC.