Solid-phase extraction with the functionalization of calcium-sensing receptors onto magnetic microspheres as an affinity probe can capture ligands selectively from herbal extract.

Magnetic solid phase extraction with the functionalization of protein onto micro- or nano-particles as a probe is favorable for the discovery of new drugs from complicated natural products. Herein, we aimed to develop a rapid method by immobilizing halogenated alkane dehalogenase (Halo)-tagged calcium-sensing receptor (CaSR) directly out of crude cell lysates onto the surface of magnetic microspheres (MM) with no need to purify protein. Thereby we achieved CaSR-functionalized MM for revealing adsorption characteristics of agonist neomycin and screening ligands from herbal medicine Radix Astragali (RA). About 43.87 mg CaSR could be immobilized per 1 g MM within 30 min, and the acquired CaSR-functionalized MM showed good stability and activity for 4 weeks. The maximum adsorption capacity of neomycin on CaSR-functionalized MM was determined as 4.70 × 10-4 ~ 3.96 × 10-4 mol/g within 277 ~ 310 K, and its adsorption isotherm characteristics described best by the Temkin model were further validated using isothermal titration calorimetry. It was inferred that CaSR's affinity for neomycin was driven by electrostatic forces in a spontaneous process when the system reached an equilibrium state. Moreover, the ligands from the RA extract were screened, three of which were assigned as astragaloside IV, ononin, and calycosin based on HPLC-MS. Our findings demonstrated that the functionalization of a receptor onto magnetic materials designed as an affinity probe has the capability to recognize its agonist and capture the ligands selectively from complex matrices like herbs.

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.

Extracellular domain of human calcium sensing receptor immobilized to silica beads as biomaterial: A rapid chromatographic method for recognizing ligands from complex matrix 'Shuangdan'.

Human calcium-sensing receptor (CaSR), a member of the G-protein-coupled receptor superfamily (GPCR), has been a therapeutic target for developing new drugs against calciotropic disorders and non-calciotropic diseases. The highly efficient methodologies for pursuing novel ligands/drugs remained a challenge due to the redundant purification processes of membrane protein in some widely-used methods including NMR, X-ray crystallography, Fluorescence Titration Spectroscopy, and Circular Dichroism. Herein, extracellular domain (ECD) of CaSR as its functional fragment was used to develop a rapid chromatographic method, which involved the synthesis of stationary phase material based on the site-specific covalent reaction of Halogenated alkane dehalogenase (Halo)-tagged ECD of CaSR in cell lysate with 6-chlorocaproic acid modified silica beads, the use of the immobilized CaSR column for revealing the interaction of three known agonists with CaSR and further screening ligands from complex matrix like Chinese herb medicine 'Shuangdan'. The immobilized CaSR column was prepared rapidly without the protein purification and retained a good stability and specificity for at least 35 days. It was revealed that one type of binding sites occurred on CaSR with the binding affinity of neomycin > gentamicin-C / kanamycin, presumably which related to the number of structural amino groups attached. This method allowed for recognizing specifically novel ligands from 'Shuangdan', demonstrating one type of binding sites on CaSR with the binding affinity of gallic acid > caffeic acid > paeonol. These results indicated that, the immobilization of a representative extracellular domain of CaSR to silica beads as biomaterial is feasible to develop a new rapid method, which can be successfully applied in screening novel ligands efficiently from complex matrices.

Insights into the development of pentylenetetrazole-induced epileptic seizures from dynamic metabolomic changes.

Epilepsy is often considered to be a progressive neurological disease, and the nature of this progression remains unclear. Understanding the overall and common metabolic changes of epileptic seizures can provide novel clues for their control and prevention. Herein, a chronic kindling animal model was established to obtain generalized tonic-clonic seizures via the repeated injections of pentylenetetrazole (PTZ) at subconvulsive dose. Dynamic metabolomic changes in plasma and urine from PTZ-kindled rats at the different kindling phases were explored using NMR-based metabolomics, in combination with behavioral assessment, brain neurotransmitter measurement, electroencephalography and histopathology. The increased levels of glucose, lactate, glutamate, creatine and creatinine, together with the decreased levels of pyruvate, citrate and succinate, ketone bodies, asparagine, alanine, leucine, valine and isoleucine in plasma and/or urine were involved in the development and progression of seizures. These altered metabolites reflected the pathophysiological processes including the compromised energy metabolism, the disturbed amino acid metabolism, the peripheral inflammation and changes in gut microbiota functions. NMR-based metabolomics could provide brain disease information by the dynamic plasma and urinary metabolic changes during chronic epileptic seizures, yielding classification of seizure stages and profound insights into controlling epilepsy via targeting deficient energy metabolism.