Synthesis of highly potent lymphocyte function-associated antigen-1 antagonists labeled with carbon-14 and with stable isotopes, part 3.

The drug candidates (2) and (3) are highly potent LFA-1 inhibitors. They were efficiently prepared labeled with carbon-14 using a palladium-catalyzed carboxylation of an iodo-precursor (5) and sodium formate-14 C to afford acid [14 C]-(6), which was coupled via an amide bond to chiral amines (7) and (8) in 52% and 48% overall yield, respectively, and with specific activities higher than 56 mCi/mmol and radiochemical purities of 99%. For stable isotopes synthesis, the amine [2 H8 ]-(7) was synthesized in three steps from 2-cyanopyridine-2 H4 using Kulinkovich-Szymonik aminocyclopropanation, followed by coupling to L-alanine-2,3,3,3-2 H4 -N-t-BOC, and then removal of the BOC-protecting group. Amide bond formation with acid (6) gave [2 H8 ]-(2) in 36% overall yield. The amine [13 C4 ,15 N]-(8) was obtained in two steps using L-threonine-14 C4 ,15 N and then coupled to acid [13 C]-(6) to give [13 C5 ,15 N]-(3) in 56% overall yield.

Discovery of 1,3-dihydro-2,1,3-benzothiadiazole 2,2-dioxide analogs as new RORC modulators.

Structure-based and pharmacophore-based virtual screening in combination with combinatorial chemistry and X-ray crystallography led to the discovery of a new class of benzothiadiazole dioxide analogs with functional activity as RORC inverse agonists. The early RORC SAR compound 14 exhibited RORC inhibition in a cell based reporter gene assay of 5.7 µM and bound to RORC with an affinity of 1.6 µM in a fluorescence polarization assay displacing a ligand binding site probe. Crystallography confirmed the binding mode of the compound in the ligand binding domain displaying the engagement of a novel sub pocket close to Ser404. Subsequent optimization yielded compounds with enhanced RORC inverse agonist activity. The most active compound 19 showed an IC50 of 440 nM in a human PBMC assay.

No differences observed among multiple clinical S1P1 receptor agonists (functional antagonists) in S1P1 receptor down-regulation and degradation.

Sphingosine-1-phosphate (S1P) is a bioactive metabolite with pleiotropic effects on multiple cellular processes in health and disease. Responses elicited by S1P are a result of binding to five specific G-protein-coupled receptors. We have developed multiple assays to systematically study the downstream signaling of these receptors, including early events such as direct receptor activation (GTPγS) as well as more distal events such as S1P1 receptor degradation. Employing such assays, we have characterized and compared multiple S1P1 agonists that are in clinical development including FTY720, BAF312, CS-0777, and other molecules from the S1P1 patent literature. Our parallel assessment has allowed us to compare their potency against S1P1, their selectivity against the four other S1P receptors, as well as species cross-reactivity. We note that all of the compounds studied signal in an identical manner through S1P1, leading to receptor degradation.