Inlfuence on Substance and Energy Metabolism of Diabetic Mouse Model of Chemical Split Fractions ofMori Cortex
10.11842/wst.2015.03.009
- VernacularTitle:桑白皮化学拆分组分对糖尿病小鼠模型物质代谢及能量代谢的影响
- Author:
Weisheng FENG
;
Peipei YUAN
;
Yan NIU
;
Yingying KE
;
Xiaolan WANG
;
Zhiyi FENG
;
Haixue KUANG
;
Xiaoke ZHENG
- Publication Type:Journal Article
- Keywords:
Mori Cortex;
chemical split fractions;
diabetes;
substance metabolism;
energy metabolism
- From:
World Science and Technology-Modernization of Traditional Chinese Medicine
2015;17(3):464-470
- CountryChina
- Language:Chinese
-
Abstract:
This article was aimed to study the impact on substance and energy metabolism by chemical split fractions of Mori Cortex among hypoglycemic diabetic mouse model, in order to explain the new hypothesis of the science connotation in nature and flavor of traditional Chinese medicine (TCM). Male Kunming mice were intraperitoneally injected with a large dose of streptozotocin (STZ) (170 mg·kg-1) to establish type 1 diabetes mellitus mouse model. Medication was given consecutively for four weeks. The enzyme-linked immunesorbent assay (ELISA) was used to detect glucosekinase (GCK), glycogen phosphorylase (PYGL), pyruvate dehydrogenase (PDH), α-ketoglutarate dehydrogenase (α-KGDHC), phosphoglycerate kinase (PGK), acetyl coenzyme A (acetyl-CoA), adenylate kinase (ADK), fumarase (FUM), cytochrome C reductase (CCR), cytochrome C oxidase (COX) and other indicators. Enzymatic detection was used to determine the content of ATP coenzyme (ATPs), the content and ratio of NAD and NADH, the content of myocardial cell Na+-K+ ATP enzyme, as well as the content of ATP and ADP. The results showed that in the model group, the expression of PYGL was increased; and the expressions of GCK and PDH were decreased. It prompted that the source of glucose increased and the expelling of glucose decreased. The glucose level was increased. The COX expression was reduced and the respiratory chain was blocked. It regulated oxidative phosphorylation and the substrate phosphorylation level. It upregulated the expression of CCR, ATPs, NAD+, PGK, α-KGDHC and ADK. However, the expression of FUM was decreased. The activity of Na+-K+ ATPase was decreased significantly. At last, the metabolic disorders appeared. Mori Cortex aqueous extracts and the chemical split fractions significantly increased the GCK and PDH level in substance metabolism among diabetic mice. The levels of PYGL, α-KGDHC, PGK and acetyl-CoA were decreased (P < 0.05, or P <0.01). Meanwhile, it increased ATP and FUM, myocardial cell Na+-K+ ATP enzyme, and COX level in the energy metabolism (P < 0.05). It decreased the level of NAD+, CCR and ATPs (P < 0.05, or P <0.01). It was concluded that both the aqueous extracts and chemical split fractions of Mori Cortex can effectively improve the substance and energy metabolism disorders of diabetic mouse model. This effect may be related to the cold nature of Mori Cortex.
