This study established the first documented case of evolved ALS inhibitor resistance in H. leporinum and revealed that the molecular basis of resistance is due to a Pro to Ser mutation in the ALS gene.
A series of 4-isoxazolyl-1,4-dihydropyridines (IDs) were prepared and characterized, and their interaction with the calcium channel was studied by patch clamp analysis. The structure-activity relationship (SAR) that emerges is distinct from the 4-aryldihydropyridines (DHPs), and affinity increases dramatically at higher holding potentials. Thus, among the 3'-arylisoxazolyl analogues p-Br > p-Cl >> p-F, and p-Cl > m-Cl > o-Cl >> o-MeO. Four of the analogues were examined by single-crystal X-ray diffractometry, and all were found to adopt an O-exo conformation in the solid state. The calculated barrier to rotation, however, suggests that rotation about the juncture between the heterocyclic rings is plausible under physiological conditions. A variable-temperature NMR study confirmed the computation. With Striessnig's computational sequence homologation procedure, a working hypothesis was derived from the data that explains the unique SAR for IDs.
More discerning than the parent: Analogues of the polyamine toxin argiotoxin 636 (shown docked in the ion channel of an ionotropic glutamate (iGlu) receptor; N blue, O red) distinguish subtypes of iGlu receptors. Depending on which of the two internal amine groups is replaced with a methylene group, the analogue inhibits one or other of two receptor subtypes as potently as the natural compound, which itself inhibits both subtypes nonselectively.
Philanthotoxins are uncompetitive antagonists of Ca2+-permeable AMPA receptors presumed to bind to the pore-forming region, but a detailed molecular mechanism for this interaction is missing. Here a small library of novel philanthotoxins was designed and synthesized using a solid-phase strategy. The biological activities were investigated at cloned and "native" AMPA receptors using electrophysiological techniques. A distinct relationship between length of the polyamine moiety and the location of a secondary amino group was observed. Fitting the data to the Woodhull equation allowed the first experimental demonstration of the relative location and orientation of the philanthotoxin molecule in the receptor. These results were corroborated by in silico studies using a homology model of the AMPA receptor ion channel. Together these studies provide strong evidence for a molecular mechanism by which polyamine toxins antagonize the AMPA receptor ion channel and provide the basis for rational development of uncompetitive antagonists of AMPA receptors.
Analogues of amino methylisoxazole propionic acid (AMPA), were prepared from a common intermediate 12, including lipophilic analogues using lateral metalation and electrophilic quenching, and were evaluated at System xc−. Both the 5-naphthylethyl-(16) and 5-naphthylmethoxymethyl-(17) analogues adopt an E-conformation in the solid state, yet while the former has robust binding at System xc−, the latter is virtually devoid of activity. The most potent analogues were amino acid naphthyl-ACPA 7g, and hydrazone carboxylic acid, 11e Y=Y′=3,5-(CF3)2, which both inhibited glutamate up-take by the System xc− transporter with comparable potency to the endogenous substrate cystine, whereas in contrast the closed isoxazolo[3,4-d] pyridazinones 13 have significantly lower activity. A preliminary pharmacophore model has been constructed to provide insight into the analogue structure-activity relationships.
Wählerischer als die Stammverbindung: Analoga des Polyamin‐Toxins Argiotoxin 636 (im Bild im Ionenkanal des ionotropen Glutamat(iGlu)‐Rezeptors; N blau, O rot) unterscheiden zwischen Unterarten der iGlu‐Rezeptoren. Je nachdem, welche der beiden internen Aminogruppen durch eine Methyleneinheit ersetzt ist, inhibieren die Analoga Rezeptoren der einen oder der anderen Unterart ebenso stark wie der unselektive Naturstoff.magnified image
Utilizing our lateral metalation coupled with Jacobsen's catalytic asymmetric amino nitrile synthesis, we have demonstrated the ability to synthesize isoxazole-containing amino acid glutamate analogues in high yield and high enantiomeric excesses. Chiral centers alpha or beta at the C-5 position do not detract from diastereoselectivity of the Jacobsen-Strecker reaction. [reaction: see text]
A major neurotransmitter, L-Glutamate must be stored, transported and received, and these processes are mediated by proteins that bind this simple yet essential amino acid. Detailed evidence continues to emerge on the structure of Glu binding proteins, which includes both receptors and transporters. It appears that receptors and transporters bind to Glu in different conformations, which may present a pharmacological opportunity. This review will compare and contrast information available on Glu Receptors (AMPA, NMDA, KA and mGlu), excitatory amino acid transporters (EAATs), the system Xc- transporter (XCT) and the vesicular Glutamate transporter (GVT). The cross-reactivity of ligands which have been previously used to characterize the glutamate binding proteins with system Xc- raises some fundamental interpretational issues regarding the mechanisms through which these analogues produce CNS damage. Although at one time it was thought that unraveling selectivity among glutamate binding proteins was an intractable problem, recently the NMDA antagonist (memantine) has been approved for general medical practice for treatment of Alzheimer's disease. Two other agents are in advanced clinical trials: an Ampakine for potential improvement of cognitive disorders, and a selective mGlu agonist for treatment of anxiety. The prospects for unraveling cross-reactivity will be weighed in light of a critical comparison of the glutamate binding protein targets.
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