An orally available Cav2.2 calcium channel inhibitor for the treatment of neuropathic pain.

BACKGROUND AND PURPOSE: Neuropathic pain affects up to 10% of the global population and is caused by an injury or a disease affecting the somatosensory, peripheral, or central nervous system. NP is characterized by chronic, severe and opioid-resistant properties. Therefore, its clinical management remains very challenging. The N-type voltage-gated calcium channel, Cav2.2, is a validated target for therapeutic intervention in chronic and neuropathic pain. The conotoxin ziconotide (Prialt®) is an FDA-approved drug that blocks Cav2.2 channel but needs to be administered intrathecally. Thus, although being principally efficient, the required application route is very much in disfavour. EXPERIMENTAL APPROACH AND KEY RESULTS: Here, we describe an orally available drug candidate, RD2, which competes with ziconotide binding to Cav2.2 at nanomolar concentrations and inhibits Cav2.2 almost completely reversible. Other voltage-gated calcium channel subtypes, like Cav1.2 and Cav3.2, were affected by RD2 only at concentrations higher than 10 µM. Data from sciatic inflammatory neuritis rat model demonstrated the in vivo proof of concept, as low-dose RD2 (5 mg·kg-1) administered orally alleviated neuropathic pain compared with vehicle controls. High-dose RD2 (50 mg·kg-1) was necessary to reduce pain sensation in acute thermal response assessed by the tail flick test. CONCLUSIONS AND IMPLICATIONS: Taken together, these results demonstrate that RD2 has antiallodynic properties. RD2 is orally available, which is the most convenient application form for patients and caregivers. The surprising and novel result from standard receptor screens opens the room for further optimization into new promising drug candidates, which address an unmet medical need.

Oral treatment with the all-d-peptide RD2 enhances cognition in aged beagle dogs - A model of sporadic Alzheimer's disease.

Disease-modifying therapies to treat Alzheimer's disease (AD) are of fundamental interest for aging humans, societies, and health care systems. Predictable disease progression in transgenic AD models favors preclinical studies employing a preventive study design with an early pre-symptomatic treatment start, instead of assessing a truly curative approach with treatment starting after diagnosed disease onset. The aim of this study was to investigate the pharmacokinetic profile and efficacy of RD2 to enhance short-term memory and cognition in cognitively impaired aged Beagle dogs - a non-transgenic model of truly sporadic AD. RD2 has previously demonstrated pharmacodynamic efficacy in three different transgenic AD mouse models in three different laboratories. Here, we demonstrate that oral treatment with RD2 significantly reduced cognitive deficits in cognitively impaired aged Beagle dogs even beyond the treatment end, which suggests in combination with the treatment dependent CSF tau oligomer decrease a disease-modifying effect of RD2 treatment.

Safety and pharmacokinetics of the orally available antiprionic compound PRI-002: A single and multiple ascending dose phase I study.

INTRODUCTION: PRI-002 is an orally available anti-amyloid beta (Aß) prionic compound developed for direct disassembly of toxic Aß oligomers relevant to Alzheimer's disease. METHODS: Two placebo-controlled clinical phase I trials with oral dosing of PRI-002 were conducted in healthy young subjects: A single ascending dose trial (4, 12, 36, 108, or 320 mg PRI-002 or placebo) in 40 participants followed by a multiple ascending dose study with daily 160 mg PRI-002 for 14 days or 320 mg for 28 days in 24 participants. The main objectives were safety, tolerability, and evaluation of pharmacokinetic (PK) parameters. RESULTS: PRI-002 was safe and well tolerated after single and multiple oral administration up to the highest doses. PRI-002 was absorbed rapidly and drug exposure increased proportional to dose. During repeated daily administration, the drug accumulated by a factor of about three. Steady-state conditions were reached after 1 to 2 weeks. CONCLUSIONS: The safety and PK results encourage further clinical development of PRI-002.

Aß oligomer eliminating compounds interfere successfully with pEAß(3-42) induced motor neurodegenerative phenotype in transgenic mice.

Currently, there are no causative or disease modifying treatments available for Alzheimer's disease (AD). Previously, it has been shown that D3, a small, fully d-enantiomeric peptide is able to eliminate low molecular weight Aß oligomers in vitro, enhance cognition and reduce plaque load in AD transgenic mice. To further characterise the therapeutic potential of D3 towards N-terminally truncated and pyroglutamated Aß (pEAß(3-42)) we tested D3 and its head-to-tail tandem derivative D3D3 both in vitro and in vivo in the new mouse model TBA2.1. These mice produce human pEAß(3-42) leading to a strong, early onset motor neurodegenerative phenotype. In the present study, we were able to demonstrate 1) strong binding affinity of both D3 and D3D3 to pEAß(3-42) in comparison to Aß(1-42) and 2) increased affinity of the tandem derivative D3D3 in comparison to D3. Subsequently we tested the therapeutic potentials of both peptides in the TBA2.1 animal model. Truly therapeutic, non-preventive treatment with D3 and D3D3 clearly slowed the progression of the neurodegenerative TBA2.1 phenotype, indicating the strong therapeutic potential of both peptides against pEAß(3-42) induced neurodegeneration.

The Aß oligomer eliminating D-enantiomeric peptide RD2 improves cognition without changing plaque pathology.

While amyloid-ß protein (Aß) aggregation into insoluble plaques is one of the pathological hallmarks of Alzheimer's disease (AD), soluble oligomeric Aß has been hypothesized to be responsible for synapse damage, neurodegeneration, learning, and memory deficits in AD. Here, we investigate the in vitro and in vivo efficacy of the D-enantiomeric peptide RD2, a rationally designed derivative of the previously described lead compound D3, which has been developed to efficiently eliminate toxic Aß42 oligomers as a promising treatment strategy for AD. Besides the detailed in vitro characterization of RD2, we also report the results of a treatment study of APP/PS1 mice with RD2. After 28 days of treatment we observed enhancement of cognition and learning behaviour. Analysis on brain plaque load did not reveal significant changes, but a significant reduction of insoluble Aß42. Our findings demonstrate that RD2 was significantly more efficient in Aß oligomer elimination in vitro compared to D3. Enhanced cognition without reduction of plaque pathology in parallel suggests that synaptic malfunction due to Aß oligomers rather than plaque pathology is decisive for disease development and progression. Thus, Aß oligomer elimination by RD2 treatment may be also beneficial for AD patients.

Large-Scale Oral Treatment Study with the Four Most Promising D3-Derivatives for the Treatment of Alzheimer's Disease.

Alzheimer's disease (AD) is a progressive neurodegenerative disorder that is associated with the aggregation of the amyloid ß protein (Aß). Aß oligomers are currently thought to be the major neurotoxic agent responsible for disease development and progression. Thus, their elimination is highly desirable for therapy development. Our therapeutic approach aims at specific and direct elimination of toxic Aß oligomers by stabilizing Aß monomers in an aggregation-incompetent conformation. We have proven that our lead compound "D3", an all d-enantiomeric-peptide, specifically eliminates Aß oligomers in vitro. In vivo, D3 enhances cognition and reduces plaque load in several transgenic AD mouse models. Here, we performed a large-scale oral proof of concept efficacy study, in which we directly compared four of the most promising D3-derivatives in transgenic mice expressing human amyloid precursor protein with Swedish and London mutations (APPSL), transgenic mice, to identify the most effective compound. RD2 and D3D3, both derived from D3 by rational design, were discovered to be the most effective derivatives in improving cognition in the Morris water maze. The performance of RD2- and D3D3-treated mice within the Morris water maze was significantly better than placebo-treated mice and, importantly, nearly as good as those of non-transgenic littermates, suggesting a complete reversal of the cognitive deficit of APPSL mice.

QIAD assay for quantitating a compound's efficacy in elimination of toxic Aß oligomers.

Strong evidence exists for a central role of amyloid ß-protein (Aß) oligomers in the pathogenesis of Alzheimer's disease. We have developed a fast, reliable and robust in vitro assay, termed QIAD, to quantify the effect of any compound on the Aß aggregate size distribution. Applying QIAD, we studied the effect of homotaurine, scyllo-inositol, EGCG, the benzofuran derivative KMS88009, ZAß3W, the D-enantiomeric peptide D3 and its tandem version D3D3 on Aß aggregation. The predictive power of the assay for in vivo efficacy is demonstrated by comparing the oligomer elimination efficiency of D3 and D3D3 with their treatment effects in animal models of Alzheimer´s disease.

Production and characterization of Escherichia coli enterohemolysin and its effects on the structure of erythrocyte membranes.

Hemolysins are cell-damaging protein toxins produced by pathogenic bacteria, which are usually released into the extracellular medium. Escherichia coli enterohemolysin is an intracellular toxin produced during the log phase of growth, with a maximal intracellular accumulation in the late log phase. In the present study, we have employed electron microscopy and SDS-PAGE to assess the effects of enterohemolysin on erythocyte membranes from different species. The erythrocyte cell damage began immediately after exposure to enterohemolysin with chemically detectable changes in cell membrane permeability, and the formation of surface lesions which increased rapidly in size. This process resulted in complete cell destruction. Ring-shaped structures with a diameter of 10nm were observed by electron microscopy after treatment of horse erythrocyte membranes with enterohemolysin. The ring structures were found clustered and irregularly distributed on the surface of the membranes. Following incubation of the toxin with horse erythrocyte ghosts and detergent-solubilization, the enterohemolysin was isolated from the cytoplasm in its membrane-bound form by sucrose density gradient. SDS-PAGE and silver staining of deoxycholate-solubilized target membranes revealed heterogeneous forms of the toxin. By using SDS-PAGE and gel filtration, the molecular weight of the toxin was estimated to be 35 kDa. With respect to species specificity, horse erythrocytes showed the highest sensitivity to the enterohemolysin, followed by human and guinea pig erythrocytes. The hemolytic sensitivity correlated with the toxin binding capacity of erythrocyte membranes of different animal species. The degree of hemolysis was unaffected by temperature in the range of 4 degrees C-37 degrees C and was optimal at pH 9.0. In contrast to pore-forming cytolysins, the hemolytic activity of enterohemolysin was enhanced continuously in the presence of increasing concentrations of dextran 4 and dextran 8 within the range of 5 to 30 mM. Trypsin sensitivity of membrane-bound enterohemolysin indicates that the cell surface is the most likely target site for this toxin. Additionally, the fact that proteinase and phosphatase inhibitors failed to inhibit lysis suggests that enterohemolysin alters and disrupts cell membranes by a detergent-like mechanism.