A series of cyclic somatostatin analogs containing a lanthionine bridge have been subjected to studies of structure-activity relationships. A direct synthesis of the thioether bridged analog (1) of sandostatin (SMS 201,995) and several lanthionine hexa-, hepta-, and octapeptides was carried out by using the method of cyclization on an oxime resin (PCOR) followed by condensation reactions in solution. The structures of the target peptides were analyzed by liquid secondary ion mass spectrometry (LSIMS) and subjected to high-energy collision-induced dissociation (CID) studies after opening of the peptide ring by proteolytic cleavage. The biological activities of these compounds have been evaluated by assaying their inhibitory potencies for the release of growth hormone (GH) from primary cultures of rat anterior pituitary cells, as well as by their binding affinities to cloned somatostatin receptors (SSTR1-5). The structural modification of sandostatin by introducing a lanthionine bridge resulted in a significantly increased receptor binding selectivity. The lanthionine octapeptide with C-terminal Thr-ol (1) showed similar high affinity for rat SSTR5 compared to somatostatin[1-14] and sandostatin. However, it exhibits about 50 times weaker binding affinity for mSSTR2b than sandostatin. Similarly, the lanthionine octapeptide with the C-terminal Thr-NH2 residue (2) has higher affinity for rSSTR5 than for mSSTR2B. Both peptides (compounds 1 and 2) have much lower potencies for inhibition of growth hormone secretion than sandostatin. This is consistent with their affinities to SSTR2, the receptor which is believed to be linked to the inhibition of growth hormone release by somatostatin and its analogs. The metabolic stability of lanthionine-sandostatin and sandostatin have been studied in rat brain homogenates. Although both compounds have a high stability toward enzymatic degradation, the lanthionine analog has a 2.4 times longer half-life than sandostatin. The main metabolites of both compounds have been isolated and identified by using an in vivo technique (cerebral microdialysis) and mass spectrometry.
We report the synthesis, bioactivity, and structure-activity relationship studies of compounds related to the Merck cyclic hexapeptide c[Pro6-Phe7-d-Trp8-Lys9-Thr10-Phe11], L-363,301 (the numbering in the sequence refers to the position of the residues in native somatostatin). The Pro residue in this compound is replaced with arylalkyl peptoid residues. We present a novel approach utilizing beta-methyl chiral substitutions to constrain the peptoid side-chain conformation. Our studies led to molecules which show potent binding and increased selectivity to the hsst2 receptor (weaker binding to the hsst3 and hsst5 receptors compared to L-363, 301). In vivo, these peptoid analogues selectively inhibit the release of growth hormone but have no effect on the inhibition of insulin. The biological assays which include binding to five recombinant human somatostatin receptors carried out in two independent laboratories and in vivo inhibition of growth hormone and insulin provide insight into the relationship between structure and biological activity of somatostatin analogues. Our results have important implications for the study of other peptide hormones and neurotransmitters.
This paper reports a detailed conformational characterization in solution by 1H-NMR in H2O and DMSO-d6 and molecular modeling simulations of cyclic peptides containing the RGDDV pharmacophore and the RGDY(Me)R pharmacophore. These two pentapeptide sequences when properly constrained in cyclic peptides are low to sub-nanomolar inhibitors of integrin alpha(v)beta3. The peptides containing the RGDDY(Me)R sequence bind potently to integrin alphaIIb3 as well. The conformations found in H2O and in DMSO-d6 solutions are valuable for the design of peptidomimetics of these two pharmacophores. The structure-activity relationships of the RGDDV and RGDY(Me)R pharmacophores within cyclic peptides are discussed. Specifically, the orientation of surface-accessible chemical features on the ligand, such as hydrophobic, positive and negative ionizable groups, which are considered to be responsible for the desired biological activity, is focused on.
We report the conformational analysis by 1H NMR in DMSO and computer simulations involving distance geometry and molecular dynamics simulations at 300K of peptoid analogs of the cyclic hexapeptide c-[Phe11-Pro6-Phe7-D-Trp8-Lys9-Thr10]. The analogs c-[Phe11-Nasp6-Phe7-D-Trp8-Lys9-Thr10](1), c-[Phe11-Ndab6Phe7-D-Trp8-Lys9-Thr10] (2) and c-[Phen11-Nlys6-Phe7-D-Trp8-Lys9-Thr10](3) where Nasp denotes N-(2-carboxyethyl) glycine, Ndab N-(2-aminoethyl) glycine and Nlys N-(4-aminobutyl) glycine are subject to conformational studies. The results of free and restrained molecular dynamics simulations at 300K are reported and give insight into the conformational behaviour of these analogs. The compounds show two sets of nuclear magnetic resonance signals corresponding to the cis and trans orientations of the peptide bond between residues 11 and 6. The backbone conformation of the cis isomers that we believe are the bioactive isomers of the three compounds are very similar to each other while there are larger variations amongst the trans isomers. The binding data to the isolated receptors show that the introduction of the Nlys residue in analog 3 leads to an enhancement of binding potency to the hsst5 receptor compared with analog 2 while maintaining identical binding potency to the hsst2 receptor. The Nasp6 analog 1 binds weakly to the hsst2 and is essentially inactive towards the other receptors. Comparison of the conformations and binding activities of these three analogs indicates that the Nlys residue extends sufficiently far to allow binding to a negatively charged binding domain on the hsst5 receptor. According to this model, the Ndab analog 2 cannot extend far enough to allow for binding to the receptor pocket. The loss of activity observed for the Nasp6 compound 1 indicates that the presence of a negatively charged residue in position 6 is unfavorable for binding to the hsst receptors.
We report the conformational analysis by 1H-NMR in DMSO and computer simulations involving distance geometry and molecular dynamics simulations of peptoid analogs of the cyclic hexapeptide c-[Phe11-Pro6-Phe7-D-Trp8-Lys9-Thr10] L-363,301 (the numbering refers to the positions in native somatostatin). The compounds c-[Phe11-Nphe6-Nal7-D-Trp8-Lys9-Thr10] (Nphe6-Nal7 analog 1), c-[Nal11-Nphe6-Phe7-D-Trp8-Lys9-Thr10] (Nal11-Nphe6 analog 2) and c-[Phe11-Nnal6-Phe7-D-Trp8-Lys9-Thr10] (Nnal6 analog 3), where Nphe denotes N-benzylglycine and Nnal denotes N-(1-naphthylmethyl)glycine, are subjected to SAR studies in order to investigate the influence of the bulky naphthyl aromatic ring on the conformation. The Nal11-Nphe6 and Nphe6-Nal7 analogs exhibit potent binding to the hsst2, hsst3 and hsst5 receptors, whereas the Nnal6 analog has decreased binding affinity to all receptors but is more selective towards the hsst2 than the other two analogs and L-363,301. The conformational search employing distance geometry, energy minimization and molecular dynamic simulations gives insight into the conformational flexibility of these analogs. The molecules adopt both cis and trans orientations of the peptide bond between residues 11 and 6. The cis isomers of these analogs adopt type II' beta-turns with D-Trp in the i + 1 position and type VIalpha beta-turns with the cis peptide bond between residues 6 and 11. The results of free and distance restrained molecular dynamics simulations at 300 K indicate that the Nphe6-Nal7 and Nal11-Nphe6 compounds adopt a preferred backbone conformation which can be described as 'folded' about residues 7 and 10. The Nnal6 analog, which binds less effectively to the hsst receptors, has a more flexible backbone structure than the Nal11-Nphe6 and Nphe6-Nal7 analogs and prefers a 'flat' structure with regard to the orientations about Phe7 and Thr10 during molecular dynamics simulations.
We report the design, synthesis, and binding affinities of a family of thioether analogues of the alpha(v)beta(3)-specific compound c[(Mpa)RGDD(tBuG)C]-NH(2). The synthesis of the thioether building blocks is scalable and produced the desired products in good yields. The linear peptides were synthesized on solid supports, followed by cyclization in solution. Our analogues demonstrate interesting binding data to the isolated receptors. In particular, the peptide c[NH-Arg-Gly-Asp-Asp-(tBuG)-Cys(S-CH(2)-CO)]NH(2) (1) exhibits differences in binding when compared to the parent compound and demonstrates potent affinity to the alpha(v)beta(3) and alpha(5)beta(1) receptors while having reduced binding to the alpha(IIb)beta(3) receptor. This result combined with the replacement of the disulfide with a thioether makes this compound interesting for further development.
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