Development of novel ACK1/TNK2 inhibitors using a fragment-based approach.

The tyrosine kinase ACK1, a critical signal transducer regulating survival of hormone-refractory cancers, is an important therapeutic target, for which there are no selective inhibitors in clinical trials to date. This work reports the discovery of novel and potent inhibitors for ACK1 tyrosine kinase (also known as TNK2) using an innovative fragment-based approach. Focused libraries were designed and synthesized by selecting fragments from reported ACK inhibitors to create hybrid structures in a mix and match process. The hybrid library was screened by enzyme-linked immunosorbent assay-based kinase inhibition and (33)P HotSpot assays. Systematic structure-activity relationship studies led to the identification of compound (R)-9b, which shows potent in vitro (IC50 = 56 nM, n = 3, (33)P HotSpot assay) and in vivo (IC50 < 2 µM, human cancer cell lines) ACK1 inhibition. Both (R)-9b and (S)-9b were stable in human plasma and displayed a long half-life (t(1/2) > 6 h).

Dual Aurora A and JAK2 kinase blockade effectively suppresses malignant transformation.

Aurora A and JAK2 kinases are involved in cell division and tumor cell survival, respectively. Here we demonstrate that ectopic expression of Aurora A and JAK2 together is more effective than each alone at inducing non-transformed cells to grow in an anchorage-independent manner and to invade. Furthermore, siRNA silencing or pharmacological inhibition of Aurora A and JAK2 with Alisertib and Ruxolitinib, respectively, is more effective than blocking each kinase alone at suppressing anchorage-dependent and -independent growth and invasion as well as at inducing apoptosis. Importantly, we have developed dual Aurora and JAK inhibitors, AJI-214 and AJI-100, which potently inhibit Aurora A, Aurora B and JAK2 in vitro. In human cancer cells, these dual inhibitors block the auto-phosphorylation of Aurora A (Thr-288) and the phosphorylation of the Aurora B substrate histone H3 (Ser-10) and the JAK2 substrate STAT3 (Tyr-705). Furthermore, AJI-214 and AJI-100 inhibit anchorage dependent and independent cell growth and invasion and induce G2/M cell cycle accumulation and apoptosis. Finally, AJI-100 caused regression of human tumor xenografts in mice. Taken together, our genetic and pharmacological studies indicate that targeting Aurora A and JAK2 together is a more effective approach than each kinase alone at inhibiting malignant transformation and warrant further advanced pre clinical investigations of dual Aurora A/JAK2 inhibitors as potential anti tumor agents.

Development of o-chlorophenyl substituted pyrimidines as exceptionally potent aurora kinase inhibitors.

The o-carboxylic acid substituted bisanilinopyrimidine 1 was identified as a potent hit (Aurora A IC(50) = 6.1 ± 1.0 nM) from in-house screening. Detailed structure-activity relationship (SAR) studies indicated that polar substituents at the para position of the B-ring are critical for potent activity. X-ray crystallography studies revealed that compound 1 is a type I inhibitor that binds the Aurora kinase active site in a DFG-in conformation. Structure-activity guided replacement of the A-ring carboxylic acid with halogens and incorporation of fluorine at the pyrimidine 5-position led to highly potent inhibitors of Aurora A that bind in a DFG-out conformation. B-Ring modifications were undertaken to improve the solubility and cell permeability. Compounds such as 9m with water-solubilizing moieties at the para position of the B-ring inhibited the autophosphorylation of Aurora A in MDA-MB-468 breast cancer cells.

Computational analysis of the structural mechanism of inhibition of chemokine receptor CXCR4 by small molecule antagonists.

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-1α. 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-1α, 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-1α) 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-1α.

Effect of Ack1 tyrosine kinase inhibitor on ligand-independent androgen receptor activity.

BACKGROUND: Androgen receptor (AR) plays a critical role in the progression of both androgen-dependent and androgen-independent prostate cancer (AIPC). Ligand-independent activation of AR in AIPC or castration resistant prostate cancer (CRPC) is often associated with poor prognosis. Recently, tyrosine kinase Ack1 has been shown to regulate AR activity by phosphorylating it at tyrosine 267 and this event was shown to be critical for AIPC growth. However, whether a small molecule inhibitor that can mitigate Ack1 activation is sufficient to abrogate AR activity on AR regulated promoters in androgen-depleted environment is not known. METHODS: We have generated two key resources, antibodies that specifically recognize pTyr267-AR and synthesized a small molecule inhibitor of Ack1, 4-amino-5,6-biaryl-furo[2,3-d]pyrimidine (named here as AIM-100) to test whether AIM-100 modulates ligand-independent AR activity and inhibits prostate cell growth. RESULTS: Prostate tissue microarray analysis indicates that Ack1 Tyr284 phosphorylation correlates positively with disease progression and negatively with the survival of prostate cancer patients. Interestingly, neither pTyr267-AR expression nor its transcriptional activation was affected by anti-androgens in activated Ack1 expressing or EGF stimulated prostate cells. However, the Ack1 inhibitor, AIM-100, not only inhibited Ack1 activation but also able to suppress pTyr267-AR phosphorylation, binding of AR to PSA, NKX3.1, and TMPRSS2 promoters, and inhibit AR transcription activity. CONCLUSION: Ack1 Tyr284 phosphorylation is prognostic of progression of prostate cancer and inhibitors of Ack1 activity could be novel therapeutic agents to treat AIPC.

Dihydro-alkylthio-benzyl-oxopyrimidines as inhibitors of reverse transcriptase: synthesis and rationalization of the biological data on both wild-type enzyme and relevant clinical mutants.

A series of novel S-DABO analogues, characterized by different substitution patterns at positions 2, 5, and 6 of the heterocyclic ring, were synthesized in a straightforward fashion by means of parallel synthesis and evaluated as inhibitors of human immunodeficiency virus type-1 (HIV-1). Most of the compounds proved to be highly active on the wild-type enzyme both in enzymatic and cellular assays, with one of them emerging as the most active reverse transcriptase inhibitor reported so far (EC50wt=25 pM). The general loss of potency displayed by the compounds toward clinically relevant mutant strains was deeply studied through a molecular modeling approach, leading to the evidence that the dynamic of the entrance in the non-nucleoside binding pocket could represent the basis of the inhibitory activity of the molecules.