On the basis of the structure-activity relationships of delta-opioid-selective peptide ligands and on a model of the proposed bioactive conformation for a potent and selective, conformationally constrained delta-opioid peptide ligand [(2S, 3R)-TMT1]DPDPE, a series of small organic peptide mimetic compounds targeted for the delta-opioid receptor have been designed, synthesized, and evaluated in radiolabeled ligand binding assays and in vitro bioassays. The new non-peptide ligands use piperazine as a template to present the most important pharmacophore groups, including phenol and phenyl groups and a hydrophobic moiety. This hydrophobic group was designed to mimic the hydrophobic character of the D-Pen residues in DPDPE, which has been found to be extremely important for increasing the binding affinity and selectivity of these non-peptide ligands for the delta-opioid receptor over the mu-opioid receptor. Compound 6f (SL-3111) showed 8 nM binding affinity and over 2000-fold selectivity for the delta-opioid receptor over the mu-opioid receptor. Both enantiomers of SL-3111 were separated, and the (-)-isomer was shown to be the compound with the highest affinity for the delta-opioid receptor found in our study (IC50 = 4.1 nM), with a selectivity very similar to that observed for the racemic compound. The phenol hydroxyl group of SL-3111 turned out to be essential to maintain high affinity for the delta-opioid receptor, which also was observed in the case of the delta-opioid-selective peptide ligand DPDPE. Binding studies of SL-3111 and [p-ClPhe4]DPDPE on the cloned wild-type and mutated human delta-opioid receptors suggested that the new non-peptide ligand has a binding profile similar to that of DPDPE but different from that of (+)-4-[((alphaR)-alpha(2S,5R)-4-allyl-2, 5-dimethyl-1-piperazinyl)-3-methoxybenzyl]-N,N-diethylbenzamide (SNC-80), another delta-opioid-selective non-peptide ligand.
On the basis of the efficient substrate for p60c-src protein tyrosine kinase (PTK) YIYGSFK-NH2 (1) (Km = 55 microM) obtained by combinatorial methods, we have designed and synthesized a series of conformationally and topographically constrained substrate-based peptide inhibitors of this enzyme, which showed IC50 values in the low-micromolar range (1-3 microM). A "rotamer scan" was performed by introducing the four stereoisomers of beta-Me(2')Nal in the postulated interaction site of the peptide inhibitor 23(IC50 = 1.6 microM). This substitution led to selective and potent inhibitors of p60c-src PTK; however, no substantial difference in potency was observed among them. This and the results of the "stereochemical scan" performed at residues 2 and 7 of 3 (peptides 19-21), which form the disulfide bond, may suggest that the enzyme active site does not have rigid topographic requirements and thus is able to achieve important conformational changes to bind the ligand as long as the pharmacophore pattern in the inhibitor is conserved. Two new potent iodo-containing nonphosphorylatable tyrosine analogues were also incorporated into our lead inhibitory sequence 23, producing the most potent inhibitors for p60c-src PTK identified thus far in our studies. Compounds 29 and 30 exhibit IC50 values of 0.13 and 0.54 microM, respectively. Peptide 29 is 420-fold more potent than the parent peptide 1. Selectivity studies of peptides 23-30 toward p60c-src, Lyn, and Lck PTK showed in general high Lyn/Src and moderate Lck/Src selectivity ratios. We found that the chi1 space constraints of the specialized amino acids, introduced at position 3 of the peptide lead 23, were not as important as the configuration of the Calpha of that residue to recognize the subtle chemical environment surrounding the active site of Src and Lck PTK, as reflected on the obtained Lck/Src selectivity ratios.
SL-3111 [1-(4-tert-butyl-3'-hydroxy)benzhydryl-4-benzylpiperazine] is a de novo designed, high-affinity and selective nonpeptide peptidomimetic agonist of the delta-opioid receptor. In a previous report we had described the unique biological characteristics of this ligand and also a need for further structural evaluation.(6) To pursue this, we have introduced a completely different heterocyclic template (2 and 3), which, based on molecular modeling studies, may present the required structural features to properly orient the pharmacophore groups. We also have made more subtle changes to the original piperazine scaffold (5 and 11). The biological activities of these compounds revealed an important participation of the scaffold in the ligand-receptor interaction. To further explore functional diversity on the scaffold, we have maintained the original piperazine ring and introduced four different functionalities at position 2 of the heterocyclic ring (15a-d; a = CH(2)-O-CH(2)-Ph; b = Me; c = CH(2)Ph; d = CH(2)OH). The biological activities observed for these compounds showed a very interesting trend in terms of the steric effects of the groups introduced at this position. A decrease of almost 2000-fold in affinity and potency at the delta-receptor was observed for 15c compared with 15b. This difference may be explained if we postulate that the bioactive conformation of these peptidomimetics is close to the minimal energy conformations calculated in our study. On the basis of these findings we have realized the importance of this position to further explore and simplify the structure of future generations of peptidomimetic ligands.
The constrained opioid peptide (2S,3R)-methyl-2Ј,6Ј-dimethyltyrosine-L-tetrahydroisoquinoline-3-carboxylic acid [(2S,3R)TMT-LTic-OH] exhibits high affinity and selectivity for the ␦-opioid receptors (Liao et al., 1997). In the present study, we examined the pharmacological properties of (2S,3R)TMT-L-Tic-OH in mouse brain. A 5Ј-O-(3-[ response curve of SNC80 to the right, with a K e value of 3.6 Ϯ 0.7 nM. In contrast, (2S,3R)TMT-L-Tic-OH had no effect on the doseresponse curve of the -selective opioid agonist, DAMGO. Warm water (55°C) tail-flick and radiant heat paw-withdrawal tests were used to determine the in vivo nociceptive properties of (2S,3R)TMT-L-Tic-OH in the mouse. Intracerebroventricular injection of (2S,3R)TMT-L-Tic-OH had no significant effect on withdrawal latencies in either nociceptive tests. (2S,3R)TMT-L-Tic-OH (30 nmol/mouse) attenuated deltorphin II-but not DAMGOmediated antinociception (40 Ϯ 13 and 100% of maximal possible effect, respectively) when administered intracerebroventricularly 10 min before the agonist. Taken together these results suggest that (2S,3R)TMT-L-Tic-OH is a potent highly selective neutral ␦-opioid antagonist in mouse brain.
Wnt pathway mutations can be found in nearly all colorectal cancers and a significant number of cancers of the liver, breast, prostate, endometrium and lung, among others. β-catenin is a key signaling hub in the Wnt pathway. Activated nuclear β-catenin forms a complex with TCF/LEF (T-cell factor/lymphoid enhancer binding factor) and drives the transcription of genes essential for cancer cell proliferation, survival, and metabolism. Blocking the β-catenin-TCF/LEF interaction offers an attractive therapeutic strategy to treat a large population of patients with WNT pathway mutations. However, β-catenin is considered as an “undruggable” target because it lacks tractable hydrophobic pockets for small-molecule binding. To address this challenge, we have successfully discovered and developed Helicon࣪ peptides targeting the β-catenin-TCF/LEF interaction. Using this novel modality, linear peptides are locked in a helical structure via a proprietary tethering technology to yield macrocyclic stapled peptides. Our helicons exhibit picomolar β-catenin binding affinity and nanomolar anti-proliferative cell-based activity. Cells treated with lead helicons followed by unbiased RNAseq GSEA indicate that the WNT/β-catenin pathways represent the top downregulated transcriptional signatures after treatment. Furthermore, PRISM cell line screening of more than 900 cell lines reveals that the most sensitive lines are enriched with APC and CTNNB1 mutations. Mechanistically, helicon treatment reduces nuclear β-catenin and alters the levels of cyclin D2/D3 and p27 in the sensitive lines. In vivo, our helicons display favorable pharmacokinetic properties, broad tissue distribution, and potent anti-tumor effects. Taken together, our data demonstrate β-catenin-targeting Helicon࣪ peptides have the potential to become the next-generation class of therapeutics to treat cancers with defined genetic mutations. Citation Format: Yaguang Si, Brian White, Sarah Cappucci, Jessica Ramirez, Charles Ponthier, Erica Visness, Kevin Ling, Peicheng Du, Minjung Choi, Ty Thomson, Josue Alfaro-Lopez, Pieter Beerepoot, Sorabh Agarwal, Paula Ortet, Miroslaw Lech, Zhi Li, Voké Olokpa, Ivan Jewett, Daniel La, Lihua Yu, John McGee, Martin Tremblay, Jonathan Hurov, Greg Verdine. Development of a novel and direct peptide Helicon࣪ inhibitor of β-catenin-TCF interaction with in vivo validation of transcriptional modulation and anti-tumor activity [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 345.
Wnt signaling pathway mutations leading to constitutive activation of the driver oncogene β-catenin occur in at least 20% of all human cancers, but β-catenin itself has remained undruggable by traditional modalities. In order to inhibit the activity of β-catenin, we have developed conformationally hyperstabilized α-helical peptides (Helicons) that are cellularly permeable and bind directly to β-catenin in order to block its interaction with TCF family of transcription factors. Starting with a helical peptide derived from phage display, a combination of structural biology insights and medicinal chemistry optimization improved β-catenin binding of lead peptides to picomolar affinity. Cellular permeability was achieved by modification of physical properties as well as cyclization strategies to enforce helicity and manage backbone amide bonds. Helicons show excellent pharmacokinetic profiles suitable for intermittent dosing. β-catenin targeting helicons demonstrate on-target activity and potent inhibition of Wnt-driven tumor growth in vivo. Citation Format: Brian H. White, Yaguang Si, Sarah Cappucci, Zhi Li, Jessica D. Ramirez, Charles M. Ponthier, Erica Visness, Peicheng Du, Minjung Choi, Pieter C. Beerepoot, Paula C. Ortet, Ivan T. Jewett, Josue Alfaro-Lopez, Sorabh Agarwal, Daniel La, Aaron Fulgham, John H. McGee, Keith Orford, Jonathan B. Hurov, Martin R. Tremblay, Gregory L. Verdine. Discovery of a HeliconTM peptide inhibitor of the beta-catenin-TCF interaction with in vivo activity [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 3094.
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