X-conopeptide pharmacophore development: Toward a novel class of norepinephrine transporter inhibitor (Xen2174) for pain

Norepinephrine (NE) amplifies the strength of descending pain inhibition, giving inhibitors of spinal NET clinical utility in the management of pain. chi-MrIA isolated from the venom of a predatory marine snail noncompetitively inhibits NET and reverses allodynia in rat models of neuropathic pain. An analogue of chi-MrIA has been found to be a suitable drug candidate. On the basis of the NMR solution structure of this related peptide, Xen2174 (3), and structure−activity relationships of analogues, a pharmacophore model for the allosteric binding of 3 to NET is proposed. It is shown that 3 interacts with NET predominantly through amino acids in the first loop, forming a tight inverse turn presenting amino acids Tyr7, Lys8, and Leu9 in an orientation allowing for high affinity interaction with NET. The second loop interacts with a large hydrophobic pocket within the transporter. Analogues based on the pharmacophore demonstrated activities that support the proposed model. On the basis of improved chemical stability and a wide therapeutic index, 3 was selected for further development and is currently in phase II clinical trials

Neutralizing monoclonal antibodies define two different functional sites in human interleukin-4

Human interleukin-4 (IL-4) is a small four-helix-bundle protein which is essential for organizing defense reactions against macroparasites, in particular helminths. Human IL-4 also appears to exert a pathophysiological role during various IgE-mediated allergic diseases. Seven different monoclonal antibodies neutralizing the activity of human IL-4 were studied in order to identify functionally important epitopes. A collection of 41 purified IL-4 variants was used to analyse how defined amino acid replacements affect binding affinity for each individual mAb. Specific amino acid positions could be assigned to four different epitopes. mAbs recognizing epitopes on helix A and/or C interfered with IL-4 receptor binding and thus inhibited IL-4 function. However, other mAbs also inhibiting IL-4 function recognized an epitope on helix D of IL-4 and did not inhibit IL-4 binding to the receptor protein. One mAb, recognizing N-terminal and C-terminal residues, partially competed for binding to the receptor. The results of these mAb epitope analyses confirm and extend previous data on the functional consequences of the amino acid replacements which showed that amino acid residues in helices A and C of IL-4 provide a binding site for the cloned IL-4 receptor and that a signalling site in helix D interacts with a further receptor protein