posted on 2018-08-17, 13:52authored bySophie J. Bradley, Julie-Myrtille Bourgognon, Helen E. Sanger, Nicholas Verity, Adrian J. Mogg, David J. White, Adrian J. Butcher, Julie A. Moreno, Colin Molloy, Timothy Macedo-Hatch, Jennifer M. Edwards, Jurgen Wess, Robert Pawlak, David J. Read, Patrick M. Sexton, Lisa M. Broad, Joern R. Steinert, Giovanna R. Mallucci, Arthur Christopoulos, Christian C. Felder, Andrew B. Tobin
The current frontline symptomatic treatment for Alzheimer's disease (AD) is whole-body upregulation of cholinergic transmission via inhibition of acetylcholinesterase. This approach leads to profound dose-related adverse effects. An alternative strategy is to selectively target muscarinic acetylcholine receptors, particularly the M1 muscarinic acetylcholine receptor (M1 mAChR), which was previously shown to have procognitive activity. However, developing M1 mAChR-selective orthosteric ligands has proven challenging. Here, we have shown that mouse prion disease shows many of the hallmarks of human AD, including progressive terminal neurodegeneration and memory deficits due to a disruption of hippocampal cholinergic innervation. The fact that we also show that muscarinic signaling is maintained in both AD and mouse prion disease points to the latter as an excellent model for testing the efficacy of muscarinic pharmacological entities. The memory deficits we observed in mouse prion disease were completely restored by treatment with benzyl quinolone carboxylic acid (BQCA) and benzoquinazoline-12 (BQZ-12), two highly selective positive allosteric modulators (PAMs) of M1 mAChRs. Furthermore, prolonged exposure to BQCA markedly extended the lifespan of diseased mice. Thus, enhancing hippocampal muscarinic signaling using M1 mAChR PAMs restored memory loss and slowed the progression of mouse prion disease, indicating that this ligand type may have clinical benefit in diseases showing defective cholinergic transmission, such as AD.
Funding
ABT, AC, and PMS received funding from a Wellcome Trust Collaborative Award (201529/Z/16/Z). ABT, SJB, AJB, and TMH were funded through a Medical Research Council programme leader grant provided by the MRC Toxicology Unit. CCF, LMB, AJM, and HES were funded by the Eli Lilly Company. JMB received funding through a Lilly Research Award Program (LRAP) grant (Eli Lilly). RP received funding from the Marie Curie grant “Extrabrain” (European Commission). AC is a senior principal research fellow and PMS a principal research fellow of the National Health and Medical Research Council of Australia. Tissue samples were from Randy Woltjer at the Oregon Alzheimer’s Disease Center. The Oregon Alzheimer’s Disease Center is supported by NIH grant P30AG008017. The authors would also like to thank Peter Scammells and Shailesh Mistry for synthesis of BQZ-12; Graham Wishart for providing the exposure data; Richard Vivier, Donna Farley, Mark Ward, and Siobhan Dennis for technical assistance; and Kok Choi Kong for initial fear-conditioning experiments.
History
Citation
Journal of Clinical Investigation, 2017, 127 (2), pp. 487-499
Author affiliation
/Organisation/COLLEGE OF LIFE SCIENCES/Biological Sciences/Molecular & Cell Biology