Synthesis and evaluation of 2,5 and 2,6 pyridine-based CXCR4 inhibitors.

Targeting the interaction between G-Protein Coupled Receptor, CXCR4, and its natural ligand CXCL12 is a leading strategy to mitigate cancer metastasis and reduce inflammation. Several pyridine-based compounds modeled after known small molecule CXCR4 antagonists, AMD3100 and WZ811, were synthesized. Nine hit compounds were identified. These compounds showed lower binding concentrations than AMD3100 (1000nM) and six of the nine compounds had an effective concentration (EC) less than or equal to WZ811 (10nM). Two of the hit compounds (2g and 2w) inhibited invasion of metastatic cells at a higher rate than AMD3100 (62%). Compounds 2g and 2w also inhibit inflammation in the same range as WZ811 in the paw edema test at 40% reduction in inflammation. These preliminary results are the promising foundation of a new class of pyridine-based CXCR4 antagonists.

Synthesis of pyridine derivatives as potential antagonists of chemokine receptor type 4.

A series of pyridine derivatives were synthesized as potential inhibitors of chemokine receptor type 4. This chemokine receptor has been linked to various disease pathways including HIV-1 proliferation, autoimmune disorders, inflammatory diseases, and cancer metastasis. The compounds were tested for activity using an affinity binding assay and an assay that tests the ability to inhibit cell invasion. Two hit compounds (2b and 2j) have been identified for further evaluation that inhibit cell invasion by at least 50% and have an effective concentration of less than 100 nM in the binding affinity assay. The structures of the synthesized compounds were confirmed by spectral data.

Sulfonamides as a new scaffold for hypoxia inducible factor pathway inhibitors.

Solid tumors generally grow under hypoxic conditions, a pathophysiological change, which activates the expression of genes responsible for malignant, aggressive, and treatment-refractory properties. Hypoxia inducible factor (HIF) is the chief transcription factor regulating hypoxia-driven gene expression. Therefore, the HIF pathway has become a critical target for cancer therapeutics development. We screened a privileged library of about 10,000 natural-product-like compounds using a cell-based assay for HIF-dependent transcriptional activity and identified several arylsulfonamide HIF pathway inhibitors. Among these compounds, the most potent ones showed an IC(50) of ∼0.5 µM in the hypoxia-responsive element (HRE)-luciferase reporter system. Further studies are needed to fully elucidate the mechanism of action of this class of compounds and their structure-activity relationship.

Synthesis and evaluation of 2,5-furan, 2,5-thiophene and 3,4-thiophene-based derivatives as CXCR4 inhibitors.

The interaction between G-Protein coupled receptor CXCR4 and its natural ligand CXCL12 has been linked to inflammation experienced by patients with Irritable Bowel Disease (IBD). Blocking this interaction could potentially reduce inflammatory symptoms in IBD patients. In this work, several thiophene-based and furan-based compounds modeled after AMD3100 and WZ811-two known antagonists that interrupt the CXCR4-CXCL12 interaction-were synthesized and analyzed. Fifteen hit compounds were identified; these compounds exhibited effective concentrations (EC) lower than 1000 nM (AMD3100) and inhibited invasion of metastatic cells by at least 45%. Selected compounds (2d, 2j, 8a) that inhibited metastatic invasion at a higher rate than WZ811 (62%) were submitted for a carrageenan inflammation test, where both 8a and 2j reduced inflammation in the same range as WZ811 (40%) but did not reduce inflammation more than 40%. Select compounds were also modeled in silico to show key residue interactions. These preliminary results with furan-based and thiophene-based analogues contribute to the new class on heterocyclic aromatic-based CXCR4 antagonists.

Symmetrical bis-tertiary amines as novel CXCR4 inhibitors.

CXCR4 inhibitors are promising agents for the treatment of cancer metastasis and inflammation. A series of novel tertiary amine derivatives targeting CXCR4 were designed, synthesized, and evaluated. The central benzene ring linker and side chains were modified and optimized to study the structure-activity relationship. Seven compounds displayed much more potent activity than the reference drug, AMD3100, in both the binding affinity assay and the blocking of Matrigel invasion functional assay. These compounds exhibited effective concentration ranging from 1 to 100 nM in the binding affinity assay and inhibited invasion from 65.3% to 100% compared to AMD3100 at 100 nM. Compound IIn showed a 50% suppressive effect against carrageenan-induced paw inflammation in a mouse model, which was as effective as the peptidic antagonist, TN14003 (48%). These data demonstrate that symmetrical bis-tertiary amines are unique CXCR4 inhibitors with high potency.

Benzenesulfonamides: a unique class of chemokine receptor type 4 inhibitors.

The interaction of CXCR4 with CXCL12 (SDF-1) plays a critical role in cancer metastasis by facilitating the homing of tumor cells to metastatic sites. Based on our previously published work on CXCR4 antagonists, we have synthesized a series of aryl sulfonamides that inhibit the CXCR4/CXCL12 interaction. Analogue bioactivities were assessed with binding affinity and Matrigel invasion assays. Computer modeling was employed to evaluate a selection of the new analogues docked into the CXCR4 X-ray structure and to rationalize discrepancies between the affinity and Matrigel in vitro assays. A lead compound displays nanomolar potency in the binding affinity assay (IC(50)=8.0 nM) and the Matrigel invasion assay (100 % blockade of invasion at 10 nM). These data demonstrate that benzenesulfonamides are a unique class of CXCR4 inhibitors with high potency.

Binding Model for the Interaction of Anticancer Arylsulfonamides with the p300 Transcription Cofactor.

Hypoxia inducible factors (HIFs) are transcription factors that activate expression of multiple gene products and promote tumor adaptation to a hypoxic environment. To become transcriptionally active, HIFs associate with cofactors p300 or CBP. Previously, we found that arylsulfonamides can antagonize HIF transcription in a bioassay, block the p300/HIF-1α interaction, and exert potent anticancer activity in several animal models. In the present work, KCN1-bead affinity pull down, (14)C-labeled KCN1 binding, and KCN1-surface plasmon resonance measurements provide initial support for a mechanism in which KCN1 can bind to the CH1 domain of p300 and likely prevent the p300/HIF-1α assembly. Using a previously reported NMR structure of the p300/HIF-1α complex, we have identified potential binding sites in the p300-CH1 domain. A two-site binding model coupled with IC50 values has allowed establishment of a modest ROC-based enrichment and creation of a guide for future analogue synthesis.

Design and synthesis of novel small-molecule inhibitors of the hypoxia inducible factor pathway.

Hypoxia, a reduction in partial oxygen pressure, is a salient property of solid tumors. Hypoxia drives malignant progression and metastasis in tumors and participates in tumor resistance to radio- and chemotherapies. Hypoxia activates the hypoxia-inducible factor (HIF) family of transcription factors, which induce target genes that regulate adaptive biological processes such as anaerobic metabolism, cell motility, and angiogenesis. Clinical evidence has demonstrated that expression of HIF-1 is strongly associated with poor patient prognosis and activation of HIF-1 contributes to malignant behavior and therapeutic resistance. Consequently, HIF-1 has become an important therapeutic target for inhibition by small molecules. Herein, we describe the design and synthesis of small molecules that inhibit the HIF-1 signaling pathway. Many of these compounds exhibit inhibitory activity in the nanomolar range. Separate mechanistic studies indicate that these inhibitors do not alter HIF-1 levels but interfere with the ability of HIF-1α/HIF-1ß to interact with cofactors p300/CBP to form an active transcriptional complex.