The Gastrointestinal (GI) microbiome and gut-brain axis are associated with the progression and pathology of Alzheimer's disease (AD). Amyloid deposition is thought to be a driver of AD, causing synap Show more
The Gastrointestinal (GI) microbiome and gut-brain axis are associated with the progression and pathology of Alzheimer's disease (AD). Amyloid deposition is thought to be a driver of AD, causing synaptic dysfunction and neuronal death in the brain. Chronic constipation is a common gastrointestinal (GI) dysmotility in AD patients, which impacts patient outcomes and quality of life. It is unknown if enteric amyloidosis disrupts myenteric neuron function and causes GI dysmotility. Untreated male and female APP/PS1 (a transgenic murine model of brain amyloidosis) and sex-matched control mice were followed until 12 months of age. A separate cohort of mice was treated with a vehicle or the beta-secretase (BACE1) inhibitor, lanabecestat, starting at 5 months of age until 7 months. GI motility was assessed in all mice by measuring whole GI transit in vivo. Propulsive colonic motility and GI smooth muscle contractions were measured ex vivo. At 7 or 12 months old, amyloidosis in the brain and myenteric plexus was determined by immunohistochemistry or ELISA; the myenteric neural density, including the cholinergic and nitrergic neurons, was evaluated by immune staining and RT-PCR; expression of pro-inflammatory factors in the GI wall was assessed by RT-PCR. By 7 months of age, male and female APP/PS1 mice developed abundant amyloid plaques in the brain. Aged untreated male APP/PS1 mice also demonstrated Aβ deposition in the colonic myenteric ganglia, which was associated with increased fecal output and faster whole GI transit starting at 4-7 months old, but vehicle- and lanabecestat-treated male APP/PS1 mice had similar GI motility to their non-genetic controls until 7 months old. None of the female APP/PS1 mice showed GI dysmotility or myenteric amyloidosis. Two months of lanabecestat treatment effectively reduced amyloid plaque burden in the brains of female APP/PS1 mice but not in male APP/PS1 mice. Treatment with lanabecestat did not affect myenteric Aβ intensity or GI motility in all APP/PS1 mice. All APP/PS1 mice did not show myenteric neuronal degeneration or inflammation until 12 months old. APP/PS1 mice do not recapitulate myenteric amyloidosis persistently and lack the phenotype of constipation observed in human AD patients; these mice should not be considered an adequate murine model for studying the role of myenteric amyloidosis in GI dysmotility. An adequate animal model with myenteric amyloidosis is required for further study. Show less
We previously showed that the anticancer drug imatinib mesylate (IMT, trade name: Gleevec) and a chemically distinct compound, DV2-103 (a kinase-inactive derivative of the potent Abl and Src kinase in Show more
We previously showed that the anticancer drug imatinib mesylate (IMT, trade name: Gleevec) and a chemically distinct compound, DV2-103 (a kinase-inactive derivative of the potent Abl and Src kinase inhibitor, PD173955) lower Aβ levels at low micromolar concentrations primarily through a lysosome-dependent mechanism that renders APP less susceptible to proteolysis by BACE1 without directly inhibiting BACE1 enzymatic activity, or broadly inhibiting the processing of other BACE1 substrates. Additionally, IMT indirectly inhibits γ-secretase and stimulates autophagy, and thus may decrease Aβ levels through multiple pathways. In two recent studies we demonstrated similar effects on APP metabolism caused by derivatives of IMT and DV2-103. In the present study, we synthesized and tested radically altered IMT isomers (IMTi's) that possess medium structural similarity to IMT. Independent of structural similarity, these isomers manifest widely differing potencies in altering APP metabolism. These will enable us to choose the most potent isomers for further derivatization. Show less