Development of high throughput screening assays and pilot screen for inhibitors of metalloproteases meprin α and ß.

Zinc metalloproteinases meprin α and meprin ß are implicated in a variety of diseases, such as fibrosis, inflammation and neurodegeneration, however, there are no selective small molecule inhibitors that would allow to study their role in these processes. To address this lack of molecular tools, we have developed high throughput screening assays to enable discovery of inhibitors of both meprin α and meprin ß and screened a collection of well characterized pharmaceutical agents (library of pharmaceutically active compounds, n = 1,280 compounds). Two compounds (PPNDS, NF449) confirmed their activity and selectivity for meprin ß. Kinetic studies revealed competitive (PPNDS) and mixed competitive/noncompetitive (NF449) inhibition mechanisms suggesting that binding occurs in meprin ß active site. Both PPNDS and NF449 exhibited low nanomolar IC50 and Ki values making them the most potent and selective inhibitors of meprin ß reported to the date. These results demonstrate the ability of meprin α and ß assays to identify selective compounds and discard artifacts of primary screening.

Discovery, design and synthesis of a selective S1P(3) receptor allosteric agonist.

Potent and selective S1P3 receptor (S1P3-R) agonists may represent important proof-of-principle tools used to clarify the receptor biological function and assess the therapeutic potential of the S1P3-R in cardiovascular, inflammatory and pulmonary diseases. N,N-Dicyclohexyl-5-propylisoxazole-3-carboxamide was identified by a high-throughput screening of MLSMR library as a promising S1P3-R agonist. Rational chemical modifications of the hit allowed the identification of N,N-dicyclohexyl-5-cyclopropylisoxazole-3-carboxamide, a S1P3-R agonist endowed with submicromolar activity and exquisite selectivity over the remaining S1P1,2,4,5-R family members. A combination of ligand competition, site-directed mutagenesis and molecular modeling studies showed that the N,N-dicyclohexyl-5-cyclopropylisoxazole-3-carboxamide is an allosteric agonist and binds to the S1P3-R in a manner that does not disrupt the S1P3-R-S1P binding. The lead molecule herein disclosed constitutes a valuable pharmacological tool to explore the molecular basis of the receptor function, and provides the bases for further rational design of more potent and drug-like S1P3-R allosteric agonists.

High throughput screening of potentially selective MMP-13 exosite inhibitors utilizing a triple-helical FRET substrate.

The major components of the cartilage extracellular matrix are type II collagen and aggrecan. Matrix metalloproteinase 13 (MMP-13) has been implicated as the protease responsible for collagen degradation in cartilage during osteoarthritis (OA). In the present study, a triple-helical FRET substrate has been utilized for high throughput screening (HTS) of MMP-13 with the MLSCN compound library (n approximately 65,000). Thirty-four compounds from the HTS produced pharmacological dose-response curves. A secondary screen using RP-HPLC validated 25 compounds as MMP-13 inhibitors. Twelve of these compounds were selected for counter-screening with 6 representative MMP family members. Five compounds were found to be broad-spectrum MMP inhibitors, 3 inhibited MMP-13 and one other MMP, and 4 were selective for MMP-13. One of the selective inhibitors was more active against MMP-13 triple-helical peptidase activity compared with single-stranded peptidase activity. Since the THP FRET substrate has distinct conformational features that may interact with MMP secondary binding sites (exosites), novel non-active site-binding inhibitors may be identified via HTS protocols utilizing such assays.

Screening of potential a disintegrin and metalloproteinase with thrombospondin motifs-4 inhibitors using a collagen model fluorescence resonance energy transfer substrate.

The major components of the cartilage extracellular matrix are type II collagen and aggrecan. Type II collagen provides cartilage with its tensile strength, whereas the water-binding capacity of aggrecan provides compressibility and elasticity. Aggrecan breakdown leads to an increase in proteolytic susceptibility of articular collagen; hence, aggrecan may also have a protective effect on type II collagen. Given their role in aggrecan degradation and differing substrate specificity profiles, the pursuit of inhibitors for both aggrecanase 1 (a disintegrin and metalloproteinase with thrombospondin motifs-4 [ADAMTS-4]) and aggrecanase 2 (ADAMTS-5) is desirable. We previously described collagen model fluorescence resonance energy transfer (FRET) substrates for aggrecan-degrading members of the ADAMTS family. These FRET substrate assays are also fully compatible with multiwell formats. In the current study, a collagen model FRET substrate was examined for inhibitor screening of ADAMTS-4. ADAMTS-4 was screened against a small compound library (n=960) with known pharmacological activity. Five compounds that inhibited ADAMTS-4>60% at a concentration of 1muM were identified. A secondary screen using reversed-phase high-performance liquid chromatography (RP-HPLC) was developed and performed for verification of the five potential inhibitors. Ultimately, piceatannol was confirmed as a novel inhibitor of ADAMTS-4, with an IC(50) value of 1muM. Because the collagen model FRET substrates have distinct conformational features that may interact with protease secondary substrate sites (exosites), nonactive site-binding inhibitors can be identified via this approach. Selective inhibitors for ADAMTS-4 would allow a more definitive evaluation of this protease in osteoarthritis and also represent a potential next generation in metalloproteinase therapeutics.