Gurmit Grewal

Discovery of Potent KIFC1 Inhibitors Using a Method of Integrated High-Throughput Synthesis and Screening

KIFC1 (HSET), a member of the kinesin-14 family of motor proteins, plays an essential role in centrosomal bundling in cancer cells, but its function is not required for normal diploid cell division. To explore the potential of KIFC1 as a therapeutic target for human cancers, a series of potent KIFC1 inhibitors featuring a phenylalanine scaffold was developed from hits identified through high-throughput screening (HTS). Optimization of the initial hits combined both design-synthesis-test cycles and an integrated high-throughput synthesis and biochemical screening method. An important aspect of this integrated method was the utilization of DMSO stock solutions of compounds registered in the corporate compound collection as synthetic reactants. Using this method, over 1500 compounds selected for structural diversity were quickly assembled in assay-ready 384-well plates and were directly tested after the necessary dilutions. Our efforts led to the discovery of a potent KIFC1 inhibitor, AZ82, which demonstrated the desired centrosome declustering mode of action in cell studies.

Identification and Optimization of Benzimidazole Sulfonamides as Orally Bioavailable Sphingosine 1-Phosphate Receptor 1 Antagonists with in Vivo Activity.

We report here a novel series of benzimidazole sulfonamides that act as antagonists of the S1P1 receptor, identified by exploiting an understanding of the pharmacophore of a high throughput screening (HTS)-derived series of compounds described previously. Lead compound 2 potently inhibits S1P-induced receptor internalization in a cell-based assay (EC50 = 0.05 μM), but has poor physical properties and metabolic stability. Evolution of this compound through structure-activity relationship development and property optimization led to in vivo probes such as 4. However, this compound was unexpectedly found to be a potent CYP3A inducer in human hepatocytes, and thus further chemistry efforts were directed at addressing this liability. By employing a pregnane X receptor (PXR) reporter gene assay to prioritize compounds for further testing in human hepatocytes, we identified lipophilicity as a key molecular property influencing the likelihood of P450 induction. Ultimately, we have identified compounds such as 46 and 47, which demonstrate the desired S1P1 antagonist activity while having greatly reduced risk of CYP3A induction in humans. These compounds have excellent oral bioavailability in preclinical species and exhibit pharmacodynamic effects of S1P1 antagonism in several in vivo models following oral dosing. Relatively modest antitumor activity was observed in multiple xenograft models, however, suggesting that selective S1P1 antagonists would have limited utility as anticancer therapeutics as single agents.

Discovery of heterocyclic sulfonamides as sphingosine 1-phosphate receptor 1 (S1P1) antagonists

We have discovered a novel class of heterocyclic sulfonamides that act as antagonists of the S1P1 receptor. While members of this series identified from a high-throughput screen showed promising levels of potency in a cell-based assay measuring the inhibition of receptor internalization, most compounds were excessively lipophilic and contained an oxidation-prone thioether moiety. As a result, such compounds suffered from poor physical properties and metabolic stability, limiting their utility as in vivo probes. By removing the thioether group and systematically developing an understanding of structure-activity relationships and the effects of lipophilicity on potency within this series, we have been able to identify potent compounds with vastly improved physical properties. A representative enantiopure triazole sulfonamide (33) has measurable bioavailability following a low (3mg/kg) oral dose in rat, highlighting an achievement of the early hit-to-lead efforts for this series.

Abstract C55: Discovery and optimization of inhibitors of the KIFC1 motor protein.

KIFC1, a kinesin-14 family protein, plays an essential role in centrosomal bundling, a strategy employed by cancer cells to avoid multipolar mitosis in the presence of amplified centrosomes. However, its function is not required for normal diploid cell division, suggesting that KIFC1 is an attractive therapeutic target for human cancers. We have recently reported the first small molecule inhibitor of KIFC1, AZ82 [1]. AZ82 binds specifically to the KIFC1/microtubule (MT) binary complex, and inhibits the MT-stimulated KIFC1 enzymatic activity with a KI of 0.043 µM. AZ82 effectively engaged with the minus-end directed KIFC1 motor in HeLa cells to reverse the monopolar spindle phenotype induced by the inhibition of the plus end-directed kinesin Eg5 by AZD4877, consistent with what was observed with genetic knock down of KiFC1 by siRNA. Additionally, treatment with AZ82 caused centrosome declustering in BT-549 breast cancer cells with amplified centrosomes. Here we further describe the chemistry approach and related structure-activity relationships that led to the discovery of AZ82. [1] http://pubs.acs.org/doi/abs/10.1021/cb400186w Citation Information: Mol Cancer Ther 2013;12(11 Suppl):C55. Citation Format: Michelle L. Lamb, Jiaquan Wu, Keith Mikule, Wendy Wang, Nancy Su, Philip Petteruti, Farzin Gharahdaghi, Erin Code, Xiahui Zhu, Kelly Jacques, Zhongwu Lai, Tao Zhang, David Boulay, Gurmit Grewal, Nicholas Keen, Bin Yang, Claudio Chuaqui, Claudio Chuaqui, Huawei Chen. Discovery and optimization of inhibitors of the KIFC1 motor protein. [abstract]. In: Proceedings of the AACR-NCI-EORTC International Conference: Molecular Targets and Cancer Therapeutics; 2013 Oct 19-23; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2013;12(11 Suppl):Abstract nr C55.