Development of ADS051, an oral, gut-restricted, small molecule neutrophil modulator for the treatment of neutrophil-mediated inflammatory diseases.

Neutrophils are an essential component of the innate immune system; however, uncontrolled neutrophil activity can lead to inflammation and tissue damage in acute and chronic diseases. Despite inclusion of neutrophil presence and activity in clinical evaluations of inflammatory diseases, the neutrophil has been an overlooked therapeutic target. The goal of this program was to design a small molecule regulator of neutrophil trafficking and activity that fulfilled the following criteria: (a) modulates neutrophil epithelial transmigration and activation, (b) lacks systemic exposure, (c) preserves protective host immunity, and (d) is administered orally. The result of this discovery program was ADS051 (also known as BT051), a low permeability, small molecule modulator of neutrophil trafficking and activity via blockade of multidrug resistance protein 2 (MRP2)- and formyl peptide receptor 1 (FPR1)-mediated mechanisms. ADS051, based on a modified scaffold derived from cyclosporine A (CsA), was designed to have reduced affinity for calcineurin with low cell permeability and, thus, a greatly reduced ability to inhibit T-cell function. In cell-based assays, ADS051 did not inhibit cytokine secretion from activated human T cells. Furthermore, in preclinical models, ADS051 showed limited systemic absorption (<1% of total dose) after oral administration, and assessment of ADS051 in human, cell-based systems demonstrated inhibition of neutrophil epithelial transmigration. In addition, preclinical toxicology studies in rats and monkeys receiving daily oral doses of ADS051 for 28 days did not reveal safety risks or ADS051-related toxicity. Our results to date support the clinical development of ADS051 in patients with neutrophil-mediated inflammatory diseases.

Daptomycin: from the mountain to the clinic, with essential help from Francis Tally, MD.

Daptomycin has been approved and successfully launched for the treatment of complicated skin and skin-structure infections caused by gram-positive pathogens [1] and bacteremia and right-sided endocarditis due to Staphylococcus aureus, including strains that are resistant to methicillin or other antibiotics [2]. The development of the drug, however, was not straightforward; it involved a cast of characters, including scientists at Eli Lilly and at Cubist Pharmaceuticals. Of most importance, the development of daptomycin involved the tenacious leadership of Dr. Francis Tally. As a tribute to Dr. Tally, we attempt to reconstruct the path of daptomycin from the mountain to the clinic.

Characterization of skeletal muscle effects associated with daptomycin in rats.

Daptomycin is a lipopeptide antibiotic with strong bactericidal effects against Gram-positive bacteria and minor side effects on skeletal muscles. The type and magnitude of the early effect of daptomycin on skeletal muscles of rats was quantified by histopathology, examination of contractile properties, Evans Blue Dye uptake, and effect on the patch repair process. A single dose of daptomycin of up to 200 mg/kg had no effect on muscle fibers. A dose of 150 mg/kg of daptomycin, twice per day for 3 days, produced a small number of myofibers (

Interaction of daptomycin with two recombinant thromboplastin reagents leads to falsely prolonged patient prothrombin time/International Normalized Ratio results.

A cluster of patients experiencing elevations of International Normalized Ratio without clinical bleeding in temporal association with daptomycin therapy was identified during postmarketing safety surveillance. A common element was the thromboplastin reagent used for the laboratory assay. The present study evaluated the effect of daptomycin on measured prothrombin time using commercially available thromboplastin reagent kits commonly used in the United States. Thirty reagent kits were obtained. Daptomycin was added to pooled normal human plasma samples to achieve final concentrations of 0-200 microg/ml. Quality control ranges were established for each reagent kit using normal and abnormal control plasmas. Triplicate assays of the prothrombin time were performed on the daptomycin-spiked plasma samples using each of the 30 kits. The activated partial thromboplastin time and thrombin time were also assessed. Statistical comparisons of interest were performed using analysis of variance with the Bonferroni t-test for multiple comparisons; alpha = 0.05 was used. Addition of daptomycin to human plasma samples dose-dependently prolonged measured prothrombin times when two recombinant thromboplastin reagents were utilized. The findings were statistically and clinically significant. No clinically meaningful effect was observed with the other reagents. The activated partial thromboplastin time and thrombin time were not affected. Prolonged International Normalized Ratio patient values were an artifact caused by the interaction of daptomycin with the in-vitro prothrombin time test reagent; an in-vivo anticoagulant effect was not observed. Healthcare providers should consider a possible drug-laboratory test interaction if prolonged prothrombin time or elevated International Normalized Ratio values are observed in patients receiving daptomycin.

OSWG Recommendations for Genotoxicity Testing of Novel Oligonucleotide-Based Therapeutics.

The Oligonucleotide Safety Working Group subcommittee on genotoxicity testing considers therapeutic oligonucleotides (ONs) unlikely to be genotoxic based on their properties and on the negative results for ONs tested to date. Nonetheless, the subcommittee believes that genotoxicity testing of new ONs is warranted because modified monomers could be liberated from a metabolized ON and incorporated into DNA and could hypothetically cause chain termination, miscoding, and/or faulty replication or repair. The standard test battery as described in Option 1 of International Conference on Harmonisation S2(R1) is generally adequate to assess such potential. However, for the in vitro assay for gene mutations, mammalian cells are considered more relevant than bacteria for most ONs due to their known responsiveness to nucleosides and their greater potential for ON uptake; on the other hand, bacterial assays may be more appropriate for ONs containing non-ON components. Testing is not recommended for ONs with only naturally occurring chemistries or for ONs with chemistries for which there is documented lack of genotoxicity in systems with demonstrated cellular uptake. Testing is recommended for ONs that contain non-natural chemical modifications and use of the complete drug product (including linkers, conjugates, and liposomes) is suggested to provide the most clinically relevant assessment. Documentation of uptake into cells comparable to those used for genotoxicity testing is proposed because intracellular exposure cannot be assumed for these large molecules. ONs could also hypothetically cause mutations through triple helix formation with genomic DNA and no tests are available for detection of such sequence-specific mutations across the entire genome. However, because the potential for triplex formation by therapeutic ONs is extremely low, this potential can be assessed adequately by sequence analysis.

Effect of daptomycin on primary rat muscle cell cultures in vitro.

Daptomycin is a lipopeptide antibiotic that has strong bactericidal activity against Gram-positive bacteria and that was previously reported to exhibit minor side effects on skeletal muscle. This study was designed to further characterize the effect of daptomycin on skeletal muscle through the use of primary cultures of muscles from rats. Our investigations demonstrated that daptomycin has a concentration-dependent and time-dependent effect on the plasma membrane of primary cultures of differentiated, spontaneously contracting rat myotubes. No effects were evident in non-differentiated myoblasts or other mononucleated cells present in cultures even at the highest daptomycin concentrations tested (6,000 microg/mL). In cultures treated with daptomycin at a concentration of 2,000 microg/mL, plasma membrane damage was observed in approximately 20-30% of differentiated myotubes; no myotube damage was detected at concentrations of 1,000 microg/mL and below. A transient loss of spontaneous myotube contractions was evident at 750 microg/mL, while at 2,000 microg/mL and above, a permanent loss of spontaneous contractility was observed. These results suggest that the putative targets for daptomycin effects on skeletal muscle are structures on the plasma membrane of highly differentiated myotubes.