Design, synthesis, and biological evaluation of selective sphingosine kinase inhibitors

Raje, Mithun

08 June 2012

Sphingosine kinase (SphK) has emerged as an attractive target for cancer therapeutics due to its role in cell proliferation. SphK phosphorylates sphingosine to form sphingosine-1-phosphate (S1P) which has been implicated as a major player in cancer growth and survival. SphK exists as two different isoforms, namely SphK1 and SphK2, which play different roles inside the cell. The dearth of isoenzyme-selective inhibitors has been a stumbling block for probing the exact roles of these two isoforms in disease progression. This report documents our efforts in developing SphK2-selective inhibitors. We provide the first demonstration of a SphK inhibitor containing a quaternary ammonium salt. We developed highly potent and moderately selective inhibitors that were cell permeable and interfered with S1P signaling inside the cell. In an effort to improve the selectivity of our inhibitors and enhance their in vivo stability, we designed and synthesized second generation inhibitors containing a heteroaromatic linker and a guanidine headgroup. These inhibitors were more potent and selective towards SphK2 and affected S1P signaling in cell cultures and various animal models. / Ph. D.

reductive amination

structure-activity relationships

guanidine inhibitors

sphingosine-1-phosphate

sphingosine kinase inhibitors

Structure-activity relationship studies and biological evaluation of selective sphingosine kinase inhibitors

Morris, Emily A.

01 June 2015

Sphingosine 1-phosphate (S1P) has become a prevalent drug discovery target due to studies implicating it to several disease pathologies such as fibrosis, sickle cell disease, inflammation, diabetes, and cancer. S1P functions to induce cell proliferation and migration. S1P signaling occurs through intracellular targets or transport outside of the cell via ABC transporters, where it acts as a ligand to G-protein coupled receptors (S1P1-5). Sphingosine kinase (SphK) 1 and 2 phosphorylate sphingosine to S1P; these are the only enzymes known to mediate the phosphoryl transfer. Inhibiting either or both SphKs helps to modulate S1P, which may be useful as a therapeutic avenue for disease states where S1P signaling has gone awry. Herein, we document our efforts in profiling the structure-activity relationships (SAR) of SphK2 through an iterative process of synthesis and biological testing. First, an SAR structured around the head and linker region of our lead molecule, SLR080811, was performed. SLR080811 has a Ki of 1.3 µM and is 5-fold selective for SphK2. The modifications performed on SLR080811 yielded two promising inhibitors: SLP120701 (SphK2 selective with a Ki of 1.2 µM) and SLP7111228 (>200 fold selective for SphK1 with a Ki of 48 nM). In vitro studies in U937 cells yielded a decrease in S1P levels with the introduction of inhibitors. Mouse studies provided insight into the pharmacokinetic effect of our SphK2-selective inhibitors, revealing an increase in S1P levels in the blood. When in vivo studies were performed with the SphK1 selective inhibitor, S1P levels in blood decreased. These molecules provide the chemical biology tools to determine the effect of modulating S1P levels in vivo. We also focused our investigation on the tail region of the pharmacophore. From this study, SLM6031434 and SLM6041418 were discovered and both proved to be more potent and selective SphK2 inhibitors than SLR080811. SLM6031434 has a Ki of 370 nM and is 23-fold selective for SphK2. SLM6041418 has a Ki of 430 nM and is 24-fold selective for SphK2. Consistent with our previous observations, in vitro studies showed a decrease in S1P levels when inhibitor was introduced. Similarly, in vivo studies resulted in an increase of S1P levels in the blood. These compounds are positioned towards animal models of disease. / Master of Science

sphingosine 1-phosphate

sphingosine kinase inhibitors

structure-activity relationships

guanidine inhibitors

Nanoparticle-Based Drug Delivery and the Impacts on Cancer Cell Biophysical Markers

Babahosseini, Hesam

19 November 2015

Cancer progression and physiological changes within the cells are accompanied by alterations in the biophysical properties. Therefore, the cell biophysical properties can serve as promising markers for cancer detection and physiological activities. To aid in the investigation of the biophysical markers of cells, a microfluidic chip has been developed which consists of a constriction channel and embedded microelectrodes. Single-cell impedance magnitudes at four frequencies and entry and travel times are measured simultaneously during their transit through the constriction channel. This microchip provides a high-throughput, label-free, automated assay to define biophysical signatures of malignant cells and monitor the therapeutic efficacy of drugs. Here, we monitored the dynamic cellular biophysical markers in response to sphingosine kinase inhibitors (SphKIs), and compared the effectiveness of drug delivery using Poly(lactic-co-glycolic acid) (PLGA) nanoparticles (NPs) loaded with SphKIs versus conventional delivery. Cells treated with SphKIs showed significantly higher impedance magnitudes at all four frequencies. The bioelectrical parameters extracted using a model also revealed that the highly aggressive breast cells treated with SphKIs shifted electrically towards that of a less malignant phenotype; SphKI-treated cells exhibited an increase in cell-channel interface resistance and a significant decrease in specific membrane capacitance. Furthermore, SphKI-treated cells became slightly more deformable as measured by a decrease in their channel entry and travel times. We observed no significant difference in the bioelectrical changes produced by SphKI delivered conventionally or with NPs. However, NPs-packaged delivery of SphKI decreased the cell deformability. In summary, the results showed that while the bioelectrical properties of the cells were dominantly affected by SphKIs, the biomechanical properties were mainly changed by the NPs. / Master of Science

MicroElectroMechanical Systems (MEMS)

Microfluidics

Biosensor

Nanoparticles

Drug Delivery

Biomechanics

Bioelectronics

Breast Cancer

MDA-MB-231

Sphingosine Kinase Inhibitors