This article aimed at exploring the effects and protective mechanism of β-CM7 on renin angiotensin system (RAS) in diabetic rats myocardial tissue. We divided 32 male SD rats into 4 groups: control group, diabetic model control group, insulin (3.7x10(-8) mol/d) treatment group and β-CM7 (7.5x10(-8) mol/d) treatment group. After 30 days, all rats were decapitated and myocardical tissues were collected immediately. After injection, β-CM7 could decrease the content of Ang II, increase the content of Angl-7. And β-CM7 could improve the mRNA of AT1 receptor and Mas receptor. β-CM7 also could improve the mRNA of ACE and ACE2, enhance the activity of ACE and ACE2. These data confirmed tli β-CM7 could activate ACE2-Angl-7-Mas axis, negative passage in RAS, to inhibit the expression ACE mnRiJA and protein in rat myocardium, alleviate the myocardial tissue damage induced by Ang II. The effect of β-CM7 on inhibiting myocardium damage might be related to ACE/ACE2 passageway.
Angiotensin II ; metabolism ; Animals ; Diabetes Mellitus, Experimental ; drug therapy ; Diabetic Cardiomyopathies ; drug therapy ; Endorphins ; pharmacology ; Male ; Myocardium ; metabolism ; pathology ; Peptide Fragments ; pharmacology ; Peptidyl-Dipeptidase A ; metabolism ; RNA, Messenger ; Rats ; Rats, Sprague-Dawley ; Receptor, Angiotensin, Type 1 ; metabolism ; Receptors, G-Protein-Coupled ; metabolism ; Renin-Angiotensin System

Objective:To analyze changes in plasma amino acid profiles in adolescents and adults with atopic dermatitis (AD) by targeted metabolomics, to further analyze differences in plasma amino acid profiles between AD patients with elevated total IgE levels and those with normal total IgE levels, as well as between AD patients with and without allergic rhinitis, and to explore the pathogenesis of AD from the perspective of metabolic pathways.Methods:From December 2021 to June 2022, 40 AD patients aged > 12 years were collected as research subjects from the Department of Dermatology, the First Affiliated Hospital of Jinzhou Medical University, and 30 healthy checkup examinees served as a control group at the same time. Plasma samples were obtained from the subjects, and high-performance liquid chromatography-mass spectrometry was performed to detect levels of metabolites in the plasma samples. Principal component analysis (PCA) and orthogonal partial least square-discriminant analysis (OPLS-DA) were carried out to analyze data and screen out differential metabolites with the variable weight value (VIP) of the first principal component being > 1 in the OPLS-DA model and the P value being < 0.05 in the t test. Possible abnormal metabolic pathways were analyzed using MetaboAnalyst 5.0 software, and differential metabolic pathways were defined as those with an impact value of > 0.1 and a P value of < 0.05. Results:PCA and OPLS-DA model analysis showed that metabolites were well differentiated among the groups, and differential metabolites and metabolic pathways were screened out. Concretely speaking, 12 differential metabolites and 8 differential metabolic pathways were identified by comparing the AD group with the control group, among which differential metabolites included arginine (metabolic levels: 28.257 ± 11.517 μmol/L vs. 21.038 ± 8.500 μmol/L, VIP = 1.32, P = 0.001), ornithine (47.597 ± 18.158 μmol/L vs. 36.937 ± 5.813 μmol/L, VIP = 1.26, P < 0.001) and histidine (78.322 ± 14.971 μmol/L vs. 100.694 ± 32.419 μmol/L, VIP = 1.33, P < 0.001), and differential metabolic pathways included arginine biosynthesis (impact = 0.482, P < 0.001) and histidine metabolism (impact = 0.221, P < 0.001). Comparisons between the AD group with elevated IgE levels and those with normal IgE levels showed 5 differential metabolites and 3 differential metabolic pathways, among which differential metabolites included lysine (313.998 ± 61.252 μmol/L vs. 285.330 ± 58.388 μmol/L, VIP = 2.25, P < 0.001) and glycine (200.807 ± 53.320 μmol/L vs. 187.056 ± 50.941 μmol/L, VIP = 1.40, P = 0.014), and differential metabolic pathways included the glyoxylate and dicarboxylate metabolic pathway (impact = 0.105, P = 0.001) ; by comparing the AD group with and without allergic rhinitis, 6 differential metabolites and 3 differential metabolic pathways were identified, among which the arginine biosynthesis metabolic pathway was highlighted (impact = 0.116, P < 0.001) . Conclusion:The plasma amino acid metabolites in adolescents and adults with AD were different from those in healthy controls, and elevated plasma levels of arginine and ornithine and decreased plasma level of histidine may be involved in the pathogenesis of AD; increased plasma levels of lysine and glycine were associated with AD with elevated IgE levels; the arginine biosynthetic metabolic pathway was related to AD complicated by allergic rhinitis.

OBJECTIVE To rapidly analyze the chemical constituents of Rubus sachalinensis Leveille by HPLC-Q-Exactive-MS/MS. METHODS Chromatographic separation was carried out on CAPCELL PAK MGII C18(4.6 mm×250 mm, 5 μm) column at the temperature of 30 ℃. The mobile phase was acetonitrile-0.1% formic acid by gradient elution, with a flow rate of 1.0 mL∙min−1, and the injection volume of 20 µL. The MS spectrum was acquired in negative ion modes using HESI ion source. RESULTS The molecular and structural formulae of the compounds were determined based on the exact mass number and ChemSpider and PubChem databases. By comparing the retention time of the corresponding reference standards and those reported in the literature, primary mass spectra, and secondary mass spectrometry pyrolysis fragments, combined with fragmentation regularity of such compounds, a total of 71 compounds were identified from Rubus sachalinensis Leveille, including 30 organic acids, 22 flavonoids, 7 triterpenoid saponins, 5 coumarins, 1 lignan, 1 gallotannin and 2 aromatic compounds. CONCLUSION This method can quickly and accurately identify the complex chemical constituents in Rubus sachalinensis Leveille, and provide scientific basis for the basic research on the medicinal substances of Rubus sachalinensis Leveille.