A rapid approach to capture the potential bioactive compounds from Rhizoma Drynariae, utilizing disease-associated mutation in calcium sensing receptor to alter the binding affinity for agonists.

Rhizoma Drynariae (RD) was used clinically to treat osteoporosis in China due to stimulating bone formation and inhibiting bone resorption, however, the bioactive constituents with the dual effect on bone are still unknown exactly. Disease-causing mutations in calcium sensing receptor (CaSR) can alter parathyroid hormone secretion and affect Ca2+ release from bone and Ca2+ reabsorption from kidney, which gives an indication that CaSR is a potential target for developing therapeutics to manage osteoporosis. Herein, a chromatographic approach was established, by immobilizing the mutant CaSR onto the surface of silica gels as stationary phase in a one-step procedure and then adding the different amino acids into mobile phase as competitors, for exploring the binding features of the known agonists and further screening ligands from RD. The mutant CaSR-coated column was prepared rapidly without the complicated purification and separation of the receptor, which had the large capacity of 13.1 mg CaSR /g silica gels and kept a good stability and specificity for at least 35 days. The CaSR mutation can weaken the binding affinities for three agonists, and the largest decreases occurred on the mutational site Thr151Met for neomycin, on the two sites of Asn118Lys and Glu191Lys for gentamicin-C, and on the site Phe612Ser for kanamycin, which gained new insights into their structure-function relationship. The potential bioactive compounds from RD were screened using the mutant CaSR-coated column and were recognized as coumaric acid 4-O-ß-D-glucopyranoside, caffeic acid, and naringin using UPLC-MS. Among them, naringin targeting CaSR gives a possible explanation that RD could manage osteoporosis. These results indicated that, such a rapid and simple method, utilizing disease-associated mutation in CaSR to alter the binding affinity for agonists, can be applied in capturing the potential bioactive compounds efficiently from complex matrices like herb medicines.

Urinary metabolomics analysis to reveal metabolic mechanism of guanxinning injection on heart failure with renal dysfunction.

Consistently, the multiple heart-kidney interactions make pharmaceutical research for cardiorenal syndrome difficult and complex. Guanxinning Injection (GXN) has been reported to provide unique advantage for treating cardiac and renal diseases compared to typical monotherapies. However, the protection mechanism of GXN is largely unknown. This study explored the acting mechanism of GXN on heart failure with renal dysfunction from a metabolic perspective. Transverse aortic constriction (TAC) surgery was performed on C57/BL/6 mice to induce heart failure with renal dysfunction. Using telmisartan as a positive control, GXN treatment was applied during the 12th to 16th week after TAC. Cardiac function and structure were examined using M-mode echocardiography, and renal function was evaluated via representative biochemical parameters and hematoxylin-eosin staining. Moreover, untargeted metabolomic analyses of urine were conducted to screen for differential substances associated with the cardiorenal protection effect of GXN. As a result, GXN provided good cardioprotective effects on left ventricular ejection fraction elevation, fractional shortening, internal diastolic, and mass maintenance. GXN also reduced TAC-induced elevation of blood urea nitrogen, and serum Cystatin C and relieved kidney pathological damage. Metabolomic analyses identified 21 differential metabolites in the TAC model group. Ten metabolites involving the metabolic pathways of carnitine synthesis, valine, leucine and isoleucine degradation, and glutamate metabolism, taurine and hypotaurine metabolism, tryptophan metabolism, arginine and proline metabolism, and purine metabolism were restored by GXN. The main cardiorenal protection mechanism of GXN was found to be related to energy metabolism and oxidative stress. Taken together, this study provides the first evidence of the metabolic protection mechanism of GXN on heart failure with renal dysfunction for the first time and provides a research basis for the application of GXN in CRS-2 pharmaceuticals.

[Gray relational analysis for the effect of nano-drug features on drug absorption].

Gray relational analysis is employed to analyze the effects of nano-drug features on phagocytosis of macrophages, including zeta potential, shape factor and scale size of drug particle, the correlation among such factors and macrophage cell is calculated. The results showed that the internalization processe is affected significantly by the zeta potential of the drug in the process of phagocytosis of macrophages, followed by the impact particle shape, and the effect of particle scale behaves relatively small.

Isopropyl 3,4,5-trihy-droxy-benzoate.

In the title compound, C(10)H(12)O(5), the dihedral angle between the benzene ring is almost coplanar with the attached C(O)-O-C group [dihedral angle = 0.32 (15)°]. In the crystal, two intermolecular O-H⋯O hydrogen bonds make R(4) (4)(26) ring mofits.