Discovery of a novel class of biphenyl pyrazole sodium channel blockers for treatment of neuropathic pain.

A series of novel biphenyl pyrazole dicarboxamides were identified as potential sodium channel blockers for treatment of neuropathic pain. Compound 20 had outstanding efficacy in the Chung rat spinal nerve ligation (SNL) model of neuropathic pain.

An automated electrophysiology serum shift assay for K(V) channels.

The presence of serum in biological samples often negatively impacts the quality of in vitro assays. However, assays tolerant of serum are useful for assessing the in vivo availability of a small molecule for its target. Electrophysiology assays of ion channels are notoriously sensitive to serum because of their reliance on the interaction of the plasma membrane with a recording electrode. Here we investigate the tolerance of an automated electrophysiology assay for a voltage-gated potassium (K(V)) channel to serum and purified plasma proteins. The delayed rectifier channel, K(V)2.1, stably expressed in Chinese hamster ovary cells produces large, stable currents on the IonWorks Quattro platform (MDS Analytical Technologies, Sunnyvale, CA), making it an ideal test case. K(V)2.1 currents recorded on this platform are highly resistant to serum, allowing recordings in as high as 33% serum. Using a set of compounds related to the K(V) channel blocker, 4-phenyl-4-[3-(2-methoxyphenyl)-3-oxo-2-azaprop-1-yl]cyclohexanone, we show that shifts in compound potency with whole serum or isolated serum proteins can be reliably measured with this assay. Importantly, this assay is also relatively insensitive to plasma, allowing the creation of a bioassay for inhibitors of K(V)2.1 channel activity. Here we show that such a bioassay can quantify the levels of the gating modifier, guangxitoxin-1E, in plasma samples from mice dosed with the peptide. This study demonstrates the utility of using an automated electrophysiology platform for measuring serum shifts and for bioassays of ion channel modulators.

A high-capacity membrane potential FRET-based assay for the sodium-coupled glucose co-transporter SGLT1.

Secondary active glucose transport is mediated by at least four members of the solute-linked carrier 5 gene family (sodium/glucose transporter [SGLT] 1-4). Human genetic disorders of SGLTs including glucose-galactose malabsorption and familial renal glucosuria have increased attention on members of this family of transporters as putative drug targets. Using human SGLT1 (hSGLT1) as a paradigm, we developed a functional assay that should be adaptable to ultra-high-throughput operation and to other SGLTs. Human embryonic kidney (HEK) 293 cells stably expressing hSGLT1 (hSGLT1/HEK293 cells) display a Na(+)-dependent, phlorizin-sensitive alpha-methyl-D-[(14)C]glucopyranoside flux with expected kinetic parameters. In electrophysiological studies with hSGLT1/HEK293 cells, substrate-dependent changes in membrane potential were observed, consistent with the electrogenic operation of hSGLT1. With the use of voltage-sensitive dyes, a membrane potential, fluorescence resonance energy transfer-based functional assay on a voltage/ion probe reader platform has been established for SGLT1. This high-capacity functional assay displays similar characteristics in terms of substrate specificity and phlorizin sensitivity to those determined by more traditional approaches and should provide a means to identify novel and selective SGLT inhibitors.

Benzazepinone Nav1.7 blockers: potential treatments for neuropathic pain.

A series of benzazepinones were synthesized and evaluated as hNa(v)1.7 sodium channel blockers. Several compounds from this series displayed good oral bioavailability and exposure and were efficacious in a rat model of neuropathic pain.

Potassium channels as targets for therapeutic intervention.

The potassium channel superfamily presents a rich source of targets for therapeutic intervention. Indeed, the development of specific potassium channel modulators could lead to the effective treatment of various diseases for which current therapies are clearly suboptimal. Numerous factors play a role in determining whether the successful clinical development of such drugs can ever be achieved. However, the large body of information accumulated over the last few years on the structure and function of potassium channels is expected to drive drug-development efforts in the pharmaceutical industry on these targets, with the ultimate goal of developing therapies that will improve patient quality of life.