Project description:The chemokine CXCL12 (SDF-1) and its cognate receptor CXCR4 are involved in a large number of physiological processes including HIV-1 infectivity, inflammation, tumorigenesis, stem cell migration, and autoimmune diseases. While previous efforts have identified a number of CXCR4 antagonists, there have been no small molecule agonists reported. Herein, we describe the identification of a novel series of CXCR4 modulators, including the first small molecules to display agonist behavior against this receptor, using a combination of structure- and ligand-based virtual screening. These agonists produce robust calcium mobilization in human melanoma cell lines which can be blocked by the CXCR4-selective antagonist AMD3100. We also demonstrate the ability of these new agonists to induce receptor internalization, ERK activation, and chemotaxis, all hallmarks of CXCR4 activation. Our results describe a new series of biologically relevant small molecules that will enable further study of the CXCR4 receptor and may contribute to the development of new therapeutics.

Project description:A key question regarding the signaling mechanism for G protein-coupled receptors (GPCRs) is what triggers agonism versus antagonism. Peptide analogs derived from the chemokine, complement fragment 5 anaphylatoxin (C5a), can act as agonists or antagonists to the C5a receptor, a member of the GPCR family [Gerber, B. O., Meng, E. C., Dotsch, V., Baranski, T. J. & Bourne, H. R. (2001) J. Biol. Chem. 276, 3394-4000]. Recently, we showed that two Cys residues engineered near a proposed binding site in the C5a receptor on transmembrane helices III and VI can selectively and reversibly trap short Cys-containing 3-mer peptides derived from C5a by disulfide bond formation [Buck, E. A., Bourne, H. & Wells, J. A. (November 18, 2004) J. Biol. Chem., 10.1074/jbc.C400500200]. Here, a library of 10,000 compounds, each containing an exchangeable thiol, was screened to identify specific small-molecule mimics that block binding of C5a. Some of the selected compounds acted as agonists and were as potent as the natural C5a ligand, and some acted as antagonists. A residue near these compounds, Ile-116 in helix III, functions as a "gatekeeper" to modulate these effects. A small substitution, Ile-116-Ala, enhanced affinity for some compounds and allowed antagonists to function as agonists; a larger substitution, Ile-116-Trp, decreased affinity and agonism. Thus, subtle changes in either the structure of the ligand or the receptor at the site between helix III, VI, and VII can switch the receptor on or off. This ligand binding and activation site may be similarly positioned in other members of the chemokine receptor family. Selective ligand trapping by reversible disulfide formation may serve to nucleate the development of small-molecule mimics.

Project description:Understanding the structural mechanism of receptor-ligand interactions for the chemokine receptor CXCR4 is essential for determining its physiological and pathological functions and for developing new therapies targeted to CXCR4. We have recently reported a structural mechanism for CXCR4 antagonism by a novel synthetic CXCR4 antagonist RCP168 and compared its effectiveness against the natural agonist SDF-1?. In the present study, using molecular docking, we further investigate the binding modes of another seven small molecules known to act as CXCR4 antagonists. The predicted binding modes were compared with previously published mutagenesis data for two of these (AMD3100 and AMD11070). Four antagonists, including AMD3100, AMD11070, FC131 and KRH-1636, bound in a similar fashion to CXCR4. Two important acidic amino acid residues (Asp262 and Glu288) on CXCR4, previously found essential for AMD3100 binding, were also involved in binding of the other ligands. These four antagonists use a binding site in common with that used by RCP168, which is a novel synthetic derivative of vMIP-II in which the first 10 residues are replaced by D-amino acids. Comparison of binding modes suggested that this binding site is different from the binding region occupied by the N-terminus of SDF-1?, the only known natural ligand of CXCR4. These observations suggest the presence of a ligand-binding site (site A) that co-exists with the agonist (SDF-1?) binding site (site B). The other three antagonists, including MSX123, MSX202 and WZ811, are smaller in size and had very similar binding poses, but binding was quite different from that of AMD3100. These three antagonists bound at both sites A and B, thereby blocking both binding and signaling by SDF-1?.

Project description:Novel small molecular ligands (SMLs) to the thyrotropin receptor (TSHR) have potential as improved molecular probes and as therapeutic agents for the treatment of thyroid dysfunction and thyroid cancer.To identify novel SMLs to the TSHR, we developed a transcription-based luciferase-cAMP high-throughput screening system and we screened 48,224 compounds from a 100K library in duplicate.We obtained 62 hits using the cut-off criteria of the mean±three standard deviations above the baseline. Twenty molecules with the greatest activity were rescreened against the parent CHO-luciferase cell for nonspecific activation, and we selected two molecules (MS437 and MS438) with the highest potency for further study. These lead molecules demonstrated no detectible cross-reactivity with homologous receptors when tested against luteinizing hormone (LH)/human chorionic gonadotropin receptor and follicle stimulating hormone receptor-expressing cells. Molecule MS437 had a TSHR-stimulating potency with an EC50 of 13×10(-8) M, and molecule MS438 had an EC50 of 5.3×10(-8) M. The ability of these small molecule agonists to bind to the transmembrane domain of the receptor and initiate signal transduction was suggested by their activation of a chimeric receptor consisting of an LHR ectodomain and a TSHR transmembrane. Molecular modeling demonstrated that these molecules bound to residues S505 and E506 for MS438 and T501 for MS437 in the intrahelical region of transmembrane helix 3. We also examined the G protein activating ability of these molecules using CHO cells co-expressing TSHRs transfected with luciferase reporter vectors in order to measure Gs?, G??, G?q, and G?12 activation quantitatively. The MS437 and MS438 molecules showed potent activation of Gs?, G?q, and G?12 similar to TSH, but neither the small molecule agonists nor TSH showed activation of the G?? pathway. The small molecules MS437 and MS438 also showed upregulation of thyroglobulin (Tg), sodium iodine symporter (NIS), and TSHR gene expression.Pharmacokinetic analysis of MS437 and MS438 indicated their pharmacotherapeutic potential, and their intraperitoneal administration to normal female mice resulted in significantly increased serum thyroxine levels, which could be maintained by repeated treatments. These molecules can therefore serve as lead molecules for further development of powerful TSH agonists.

Project description:Chemokine receptors are critical regulators of cell migration in the context of immune surveillance, inflammation, and development. The G protein-coupled chemokine receptor CXCR4 is specifically implicated in cancer metastasis and HIV-1 infection. Here we report five independent crystal structures of CXCR4 bound to an antagonist small molecule IT1t and a cyclic peptide CVX15 at 2.5 to 3.2 angstrom resolution. All structures reveal a consistent homodimer with an interface including helices V and VI that may be involved in regulating signaling. The location and shape of the ligand-binding sites differ from other G protein-coupled receptors and are closer to the extracellular surface. These structures provide new clues about the interactions between CXCR4 and its natural ligand CXCL12, and with the HIV-1 glycoprotein gp120.

Project description:Mps1, a dual-specificity kinase, is required for the proper functioning of the spindle assembly checkpoint and for the maintenance of chromosomal stability. As Mps1 function has been implicated in numerous phases of the cell cycle, the development of a potent, selective small-molecule inhibitor of Mps1 should facilitate dissection of Mps1-related biology. We describe the cellular effects and Mps1 cocrystal structures of new, selective small-molecule inhibitors of Mps1. Consistent with RNAi studies, chemical inhibition of Mps1 leads to defects in Mad1 and Mad2 establishment at unattached kinetochores, decreased Aurora B kinase activity, premature mitotic exit and gross aneuploidy, without any evidence of centrosome duplication defects. However, in U2OS cells having extra centrosomes (an abnormality found in some cancers), Mps1 inhibition increases the frequency of multipolar mitoses. Lastly, Mps1 inhibitor treatment resulted in a decrease in cancer cell viability.

Project description:To find out potential GDNF family receptor α1 (GFRα1) agonists, small molecules were built up by molecular fragments according to the structure-based drug design approach. Molecular docking was used to identify their binding modes to the biological target GFRα1 in GDNF-binding pocket. Thereafter, commercially available compounds based on the best predicted structures were searched from ZINC and MolPort databases (similarity ≥ 80%). Five compounds from the ZINC library were tested in phosphorylation and luciferase assays to study their ability to activate GFRα1-RET. A bidental compound with two carboxyl groups showed the highest activity in molecular modeling and biological studies. However, the relative position of these groups was important. The meta-substituted structure otherwise identical to the most active compound 2-[4-(5-carboxy-1H-1,3-benzodiazol-2-yl)phenyl]-1H-1,3-benzodiazole-5-carboxylic acid was inactive. A weaker activity was detected for a compound with a single carboxyl group, that is, 4-(1,3-benzoxazol-2-yl)benzoic acid. The substitution of the carboxyl group by the amino or acetamido group also led to the loss of the activity.

Project description:Resistance to conventional antiestrogens is a major cause of treatment failure and, ultimately, death in breast cancer.The objective of the study was to identify small-molecule estrogen receptor (ER)-? antagonists that work differently from tamoxifen and other selective estrogen receptor modulators.Based on in silico screening of a pharmacophore database using a computed model of the BRCA1-ER-? complex (with ER-? liganded to 17?-estradiol), we identified a candidate group of small-molecule compounds predicted to bind to a BRCA1-binding interface separate from the ligand-binding pocket and the coactivator binding site of ER-?. Among 40 candidate compounds, six inhibited estradiol-stimulated ER-? activity by at least 50% in breast carcinoma cells, with IC50 values ranging between 3 and 50 ?M. These ER-? inhibitory compounds were further studied by molecular and cell biological techniques.The compounds strongly inhibited ER-? activity at concentrations that yielded little or no nonspecific toxicity, but they produced only a modest inhibition of progesterone receptor activity. Importantly, the compounds blocked proliferation and inhibited ER-? activity about equally well in antiestrogen-sensitive and antiestrogen-resistant breast cancer cells. Representative compounds disrupted the interaction of BRCA1 and ER-? in the cultured cells and blocked the interaction of ER-? with the estrogen response element. However, the compounds had no effect on the total cellular ER-? levels.These findings suggest that we have identified a new class of ER-? antagonists that work differently from conventional antiestrogens (eg, tamoxifen and fulvestrant).

Project description:Ligand-independent activation of EphA2 receptor kinase promotes cancer metastasis and invasion. Activating EphA2 receptor tyrosine kinase with small molecule agonist is a novel strategy to treat EphA2 overexpressing cancer. In this study, we performed a lead optimization of a small molecule Doxazosin that was identified as an EphA2 receptor agonist. 33 new analogs were developed and evaluated; a structure-activity relationship was summarized based on the EphA2 activation of these derivatives. Two new derivative compounds 24 and 27 showed much improved activity compared to Doxazosin. Compound 24 possesses a bulky amide moiety, and compound 27 has a dimeric structure that is very different to the parental compound. Compound 27 with a twelve-carbon linker of the dimer activated the kinase and induced receptor internalization and cell death with the best potency. Another dimer with a six-carbon linker has significantly reduced potency compared to the dimer with a longer linker, suggesting that the length of the linker is critical for the activity of the dimeric agonist. To explore the receptor binding characteristics of the new molecules, we applied a docking study to examine how the small molecule binds to the EphA2 receptor. The results reveal that compounds 24 and 27 form more hydrogen bonds to EphA2 than Doxazosin, suggesting that they may have higher binding affinity to the receptor.

Project description:The peptide hormone glucagon-like peptide (GLP)-1 has important actions resulting in glucose lowering along with weight loss in patients with type 2 diabetes. As a peptide hormone, GLP-1 has to be administered by injection. Only a few small-molecule agonists to peptide hormone receptors have been described and none in the B family of the G protein coupled receptors to which the GLP-1 receptor belongs. We have discovered a series of small molecules known as ago-allosteric modulators selective for the human GLP-1 receptor. These compounds act as both allosteric activators of the receptor and independent agonists. Potency of GLP-1 was not changed by the allosteric agonists, but affinity of GLP-1 for the receptor was increased. The most potent compound identified stimulates glucose-dependent insulin release from normal mouse islets but, importantly, not from GLP-1 receptor knockout mice. Also, the compound stimulates insulin release from perfused rat pancreas in a manner additive with GLP-1 itself. These compounds may lead to the identification or design of orally active GLP-1 agonists.