The role of the N-terminal and mid-region residues of substance P in regulating functional selectivity at the tachykinin NK1 receptor.

Previous studies have shown that tachykinin peptide ligands of the tachykinin NK1 receptor exhibit functional selectivity with respect to signal activation and desensitization. The differences are most dramatic between the naturally occurring peptides substance P (RPKPQQFFGLM-NH2) and ranatachykinin C (HNPASFIGLM-NH2). To understand the structural features of the peptides that underlie these differences, four peptide analogs have been designed and tested. The analogs were designed to assess the major structural differences between substance P and ranatachykinin C, including the role of the N-terminal Arg and the substitution of the mid-region Glns with Ala and Ser (Q5 replaced with A and/or Q6 replaced with S). Receptor binding, receptor activation of intracellular calcium fluxes, and receptor desensitization of the rat tachykinin NK1 receptor were quantified for each ligand. All of the peptides bound to the rat tachykinin NK1 receptor with high affinity, produced robust calcium signal activation, and led to agonist-induced receptor desensitization. It was found that deletion of the N-terminal Arg of substance P or replacement of either or both Q5 and Q6 altered the functional selectivity of substance P based on the relationship of receptor binding to receptor activation and activation to desensitization. When considered in light of our previously published nuclear magnetic resonance structure data, the data presented herein suggest that the one, five and six positions of the substance P backbone are key structural residues that govern the relative degree of tachykinin peptide-mediated receptor signaling and desensitization.

Tandem reactions of 1,3-diacid chlorides with 2-methylimidazoline and 2-methyl-1,4,5,6-tetrahydropyrimidine: one-pot synthesis of 1,8-naphthyridinetetraones.

The reactions of 2-methylimidazoline and 2-methyl-1,4,5,6-tetrahydropyrimidine with 1,3-diacid chlorides, in the presence of Et3N in refluxing MeCN give highly functionalized potentially bioactive 1,8-naphthyridinetetraones. 2-Methylimidazoline and 2-methyl-1,4,5,6-tetrahydropyrimidine can be viewed as tridentate nucleophiles which give four consecutive tandem nucleophilic attacks on electrophiles.

Conformational comparisons of a series of tachykinin peptide analogs.

Previous studies have shown differences in the biological activity and the structure of two naturally occurring tachykinin peptides, substance P (SP, RPKPQQFFGLM-NH2) and ranatachykinin C (RTKC, HNPASFIGLM-NH2). To further understand the basis for these differences, four analogs that selectively incorporate the amino acid differences between SP and RTKC have been synthesized for study. The four peptide analogs studied have the following amino acid sequences: SP2-11, also known as des-Arg SP (PKPQQFFGLM-NH2); Q5A-SP (RPKPAQFFGLM-NH2); Q6S-SP (RPKPQSFFGLM-NH2); and Q5AQ6S-SP (RPKPASFFGLM-NH2). Nuclear magnetic resonance spectroscopy and molecular modeling calculations were performed on SP, RTKC, SP2-11, Q5A-SP, Q6S-SP, and Q5AQ6S-SP to compare their conformational differences and similarities in the presence of the membrane mimetic system sodium dodecyl sulfate. The molecular modeling data of the analogs Q5A-SP and Q6S-SP show residues 1-3 have a random conformation and residues 4-8 have a helical structure, while the C-terminus contains a poly C7 conformation that is similar to SP but different from RTKC. The molecular modeling data of the analogs SP2-11 and Q5AQ6S-SP show a continuous helix conformation for residues 4-11 at the C-terminus, which is different from SP but similar to RTKC. These structural differences are related to the functional differences of binding of the peptides at the SP receptor (NK1).