Minimization of drug-drug interaction risk and candidate selection in a natural product-based class of gamma-secretase modulators.

Early lead compounds in this gamma secretase modulator series were found to potently inhibit CYP3A4 and other human CYP isoforms increasing their risk of causing drug-drug-interactions (DDIs). Using structure-activity relationships and CYP3A4 structural information, analogs were developed that minimized this DDI potential. Three of these new analogs were further characterized by rat PK, rat PK/PD and rat exploratory toxicity studies resulting in selection of SPI-1865 (14) as a preclinical development candidate.

Efficacy of SPI-1865, a novel gamma-secretase modulator, in multiple rodent models.

INTRODUCTION: Modulation of the gamma-secretase enzyme, which reduces the production of the amyloidogenic Aß42 peptide while sparing the production of other Aß species, is a promising therapeutic approach for the treatment of Alzheimer's disease. Satori has identified a unique class of small molecule gamma-secretase modulators (GSMs) capable of decreasing Aß42 levels in cellular and rodent model systems. The compound class exhibits potency in the nM range in vitro and is selective for lowering Aß42 and Aß38 while sparing Aß40 and total Aß levels. In vivo, a compound from the series, SPI-1865, demonstrates similar pharmacology in wild-type CD1 mice, Tg2576 mice and Sprague Dawley rats. METHODS: Animals were orally administered either a single dose of SPI-1865 or dosed for multiple days. Aß levels were measured using a sensitive plate-based ELISA system (MSD) and brain and plasma exposure of drug were assessed by LC/MS/MS. RESULTS: In wild-type mice using either dosing regimen, brain Aß42 and Aß38 levels were decreased upon treatment with SPI-1865 and little to no statistically meaningful effect on Aß40 was observed, reflecting the changes observed in vitro. In rats, brain Aß levels were examined and similar to the mouse studies, brain Aß42 and Aß38 were lowered. Comparable changes were also observed in the Tg2576 mice, where Aß levels were measured in brain as well as plasma and CSF. CONCLUSIONS: Taken together, these data indicate that SPI-1865 is orally bioavailable, brain penetrant, and effective at lowering Aß42 in a dose responsive manner. With this unique profile, the class of compounds represented by SPI-1865 may be a promising new therapy for Alzheimer's disease.

An improved cell-based method for determining the γ-secretase enzyme activity against both Notch and APP substrates.

γ-Secretase modulators (GSM), which reduce amyloidogenic Aß(42) production while maintaining total Aß levels, and Notch-sparing γ-secretase inhibitors (GSIs) are promising therapies for the treatment of Alzheimer's Disease (AD). To have a safety margin for therapeutic use, GSMs and GSIs need to allow Notch intracellular domain (NICD) production, while preventing neurotoxic Aß peptide production. Typically, GSI and GSM effects on these substrates are determined using two different cell lines, one for the measurement of enzyme activity against each substrate. However, predicting selectivity for different substrates across cell systems may reduce the reliability of such ratios such that the in vitro data are not useful for predicting in vivo safety margins. This is especially concerning since the IC(50)'s of some GSIs vary depending upon the level of APP expression in a cell line. To circumvent this problem, we utilized the SUP-T1 cell line which expresses a truncated Notch receptor fragment that does not need sheddase cleavage to be a γ-secretase substrate. When combined with a sensitive method of measuring Aß production, this assay system allows both substrates to be measured simultaneously, reducing the potential to calculate imprecise selectivity margins. To demonstrate the value of this system, known GSIs and GSMs were examined in the SUP-T1 dual substrate assay. IC(50)'s were determined for both substrates and the in vitro selectivity margin was calculated. These data suggest using a single cell line is a more accurate prediction of the fold difference between NICD inhibition and Aß(42) lowering for therapeutically promising GSIs and GSMs.

An ultra-specific avian antibody to phosphorylated tau protein reveals a unique mechanism for phosphoepitope recognition.

Highly specific antibodies to phosphoepitopes are valuable tools to study phosphorylation in disease states, but their discovery is largely empirical, and the molecular mechanisms mediating phosphospecific binding are poorly understood. Here, we report the generation and characterization of extremely specific recombinant chicken antibodies to three phosphoepitopes on the Alzheimer disease-associated protein tau. Each antibody shows full specificity for a single phosphopeptide. The chimeric IgG pT231/pS235_1 exhibits a K(D) of 0.35 nm in 1:1 binding to its cognate phosphopeptide. This IgG is murine ortholog-cross-reactive, specifically recognizing the pathological form of tau in brain samples from Alzheimer patients and a mouse model of tauopathy. To better understand the underlying binding mechanisms allowing such remarkable specificity, we determined the structure of pT231/pS235_1 Fab in complex with its cognate phosphopeptide at 1.9 Å resolution. The Fab fragment exhibits novel complementarity determining region (CDR) structures with a "bowl-like" conformation in CDR-H2 that tightly and specifically interacts with the phospho-Thr-231 phosphate group, as well as a long, disulfide-constrained CDR-H3 that mediates peptide recognition. This binding mechanism differs distinctly from either peptide- or hapten-specific antibodies described to date. Surface plasmon resonance analyses showed that pT231/pS235_1 binds a truly compound epitope, as neither phosphorylated Ser-235 nor free peptide shows any measurable binding affinity.

Robust changes in expression of brain-derived neurotrophic factor (BDNF) mRNA and protein across the brain do not translate to detectable changes in BDNF levels in CSF or plasma.

Adult rats were treated acutely with peripheral kainic acid (KA), and changes in brain-derived neurotrophic factor (BDNF) mRNA and protein were tracked over time across multiple brain regions. Despite robust elevation in both mRNA and protein in multiple brain regions, plasma BDNF was unchanged and cerebrospinal fluid (CSF) BDNF levels remained undetectable. Primary neurons were then treated with KA. BDNF was similarly elevated within neurons, but was undetectable in neuronal media. Thus, while deficits in BDNF signaling have been implicated in a number of diseases, these data suggest that extracellular concentrations of BDNF may not be a facile biomarker for changes in neurons.

Modulation of gamma-secretase for the treatment of Alzheimer's disease.

The Amyloid Hypothesis states that the cascade of events associated with Alzheimer's disease (AD)-formation of amyloid plaques, neurofibrillary tangles, synaptic loss, neurodegeneration, and cognitive decline-are triggered by Aß peptide dysregulation (Kakuda et al., 2006, Sato et al., 2003, Qi-Takahara et al., 2005). Since γ-secretase is critical for Aß production, many in the biopharmaceutical community focused on γ-secretase as a target for therapeutic approaches for Alzheimer's disease. However, pharmacological approaches to control γ-secretase activity are challenging because the enzyme has multiple, physiologically critical protein substrates. To lower amyloidogenic Aß peptides without affecting other γ-secretase substrates, the epsilon (ε) cleavage that is essential for the activity of many substrates must be preserved. Small molecule modulators of γ-secretase activity have been discovered that spare the ε cleavage of APP and other substrates while decreasing the production of Aß(42). Multiple chemical classes of γ-secretase modulators have been identified which differ in the pattern of Aß peptides produced. Ideally, modulators will allow the ε cleavage of all substrates while shifting APP cleavage from Aß(42) and other highly amyloidogenic Aß peptides to shorter and less neurotoxic forms of the peptides without altering the total Aß pool. Here, we compare chemically distinct modulators for effects on APP processing and in vivo activity.