The human pyridoxal kinase, a plausible target for ginkgotoxin from Ginkgo biloba.

Ginkgotoxin (4'-O-methylpyridoxine) occurring in the seeds and leaves of Ginkgo biloba, is an antivitamin structurally related to vitamin B(6). Ingestion of ginkgotoxin triggers epileptic convulsions and other neuronal symptoms. Here we report on studies on the impact of B(6) antivitamins including ginkgotoxin on recombinant homogeneous human pyridoxal kinase (EC 2.7.1.35). It is shown that ginkgotoxin serves as an alternate substrate for this enzyme with a lower K(m) value than pyridoxal, pyridoxamine or pyridoxine. Thus, the presence of ginkgotoxin leads to temporarily reduced pyridoxal phosphate formation in vitro and possibly also in vivo. Our observations are discussed in light of Ginkgo medications used as nootropics.

Molecular dynamics simulation of the human adenosine A3 receptor: agonist induced conformational changes of Trp243.

The adenosine A(3) receptor together with rhodopsin belongs to Class A of the G-protein coupled receptors. As the crystal structure of bovine rhodopsin represents the dark (inactive) state of the receptor, the details of GPCR activation are still unknown. In this molecular dynamics study we investigate how the homology model of the human adenosine A(3) receptor responds to ligand exposure. To this end we placed the homology model in a POPC membrane model. After equilibrating for 13 ns an agonist (Cl-IB-MECA) and an inverse agonist (PSB-10) were placed inside the putative binding pocket. In the following 10 ns molecular dynamics simulation we observed a different behaviour of the side-chain torsions of Trp243(6.48), depending on the presence or absence of the agonist or inverse agonist. This conformational change of Trp243 correlates with the assumed influence of ligands on receptor activation. Other predicted conformational changes of the receptor could not be observed yet. So Trp243 may represent the first switch in receptor activation.

Novel amino acid derived natural products from the ascidian Atriolum robustum: identification and pharmacological characterization of a unique adenosine derivative.

Investigation of the methanolic extract of the Australian ascidian Atriolum robustum led to the isolation and characterization of five new amino acid derived structures (1-5). The structures were elucidated employing spectroscopic techniques (NMR, MS, UV, and IR). The absolute stereochemistry of 1 and 2 was established by chemical degradation, derivatization, and chiral GC-MS analysis. Structures 4 and 5 are complex nucleosides containing rare methylthioadenosine and methylsulfinyladenosine moieties, respectively. In radioligand binding studies the 5'-deoxy-5'-methylthioadenosine-2',3'-diester 4 exhibited affinity for A(1) and A(3) adenosine receptors with K(i) values below 10 microM. Its affinity was somewhat lower for A(2A) (K(i) = 17 microM) and much lower for A(2B) adenosine receptors. Analytical experiments using capillary electrophoresis showed that compound 4 was stable under the conditions of radioligand binding studies. Incubation with carboxylesterase resulted in slow hydrolysis of the adenosine derivative to 5'-deoxy-5'-methylthioadenosine (MTA), which was about 10-fold more potent at adenosine receptors than compound 4. Thus, the 2',3'-diester derivative 4 may act as a lipophilic prodrug of MTA in addition to its own adenosine receptor activity. GTP shift experiments indicated that the adenosine derivative was a partial agonist at A(1) adenosine receptors of rat brain cortical membranes. Compound 4 inhibited cAMP accumulation in Chinese hamster ovary (CHO) cell membranes recombinantly expressing the human A(3) adenosine receptor, thus indicating that the adenosine derivative also acted as a partial agonist at A(3)ARs. Homology models of the A(1) and the A(3) adenosine receptors in their putative active and inactive conformations were built and used for docking of the sterically demanding compound 4. It was found that this ligand fit well into the binding pockets of both receptor subtypes because of its highly flexible structure, although in somewhat different binding modes.