Pharmacologic enrichment of exosome yields and mitochondrial cargo.

In studies with human participants, exosome-based biospecimens can facilitate unique biomarker assessments. As exosome cargos can include mitochondrial components, there is interest in using exosomes to inform the status of an individual's mitochondria. Here, we evaluated whether targeted pharmacologic manipulations could influence the quantity of exosomes shed by cells, and whether these manipulations could impact their mitochondrial cargos. We treated human SH-SY5Y cells with bafilomycin A1, which interferes with general autophagy and mitophagy by inhibiting lysosome acidification and lysosome-autophagosome fusion; deferiprone (DFP), which enhances receptor-mediated mitophagy; or both. Exosome fractions from treated cells were harvested from the cell medium and analyzed for content including mitochondria-derived components. We found bafilomycin increased particle yields, and a combination of bafilomycin plus DFP consistently increased particle yields and mitochondria-associated content. Specifically, the exosome fractions from the bafilomycin plus DFP-treated cells contained more mitochondrial DNA (mtDNA), mtDNA-derived mRNA transcripts, and citrate synthase protein. Our data suggest pharmacologic manipulations that enhance mitophagy initiation, while inhibiting the lysosomal digestion of autophagosomes and multivesicular bodies, could potentially enhance the sensitivity of exosome-based biomarker assays intended to inform the status of an individual's mitochondria.

Alzheimer's disease clinical trial update 2019-2021.

The current clinical trial landscape targeting Alzheimer's disease (AD) is reviewed in the context of studies completed from 2019 to 2021. This review focuses on available data for observational and phase II/III clinical trial results, which will have the most impact on the field. ClinicalTrials.gov, the United States (US) comprehensive federal registry, was queried to identify completed trials. There are currently 226 interventional clinical trials and 51 observational studies completed, suspended, terminated, or withdrawn within our selected time frame. This review reveals that the role of biomarkers is expanding and although many lessons have been learned, many challenges remain when targeting disease modification of AD through amyloid and tau. In addition, to halt or slow clinical progression of AD, new clinical and observational trials are focusing on prevention as well as the role of more diverse biological processes known to influence AD pathology.

Aerobic exercise improves hippocampal blood flow for hypertensive Apolipoprotein E4 carriers.

Cerebrovascular dysfunction likely contributes causally to Alzheimer's disease (AD). The strongest genetic risk factor for late-onset AD, Apolipoprotein E4 (APOE4), may act synergistically with vascular risk to cause dementia. Therefore, interventions that improve vascular health, such as exercise, may be particularly beneficial for APOE4 carriers. We assigned cognitively normal adults (65-87 years) to an aerobic exercise intervention or education only. Arterial spin labeling MRI measured hippocampal blood flow (HBF) before and after the 52-week intervention. We selected participants with hypertension at enrollment (n = 44). For APOE4 carriers, change in HBF (ΔHBF) was significantly (p = 0.006) higher for participants in the exercise intervention (4.09 mL/100g/min) than the control group (-2.08 mL/100g/min). There was no difference in ΔHBF between the control (-0.32 mL/100g/min) and exercise (-0.54 mL/100g/min) groups for non-carriers (p = 0.918). Additionally, a multiple regression showed an interaction between change in systolic blood pressure (ΔSBP) and APOE4 carrier status on ΔHBF (p = 0.035), with reductions in SBP increasing HBF for APOE4 carriers only. Aerobic exercise improved HBF for hypertensive APOE4 carriers only. Additionally, only APOE4 carriers exhibited an inverse relationship between ΔSBP and ΔHBF. This suggests exercise interventions, particularly those that lower SBP, may be beneficial for individuals at highest genetic risk of AD.ClinicalTrials.gov Identifier: NCT02000583.

Safety and target engagement profile of two oxaloacetate doses in Alzheimer's patients.

INTRODUCTION: Brain bioenergetics are defective in Alzheimer's disease (AD). Preclinical studies find oxaloacetate (OAA) enhances bioenergetics, but human safety and target engagement data are lacking. METHODS: We orally administered 500 or 1000 mg OAA, twice daily for 1 month, to AD participants (n = 15 each group) and monitored safety and tolerability. To assess brain metabolism engagement, we performed fluorodeoxyglucose positron emission tomography (FDG PET) and magnetic resonance spectroscopy before and after the intervention. We also assessed pharmacokinetics and cognitive performance. RESULTS: Both doses were safe and tolerated. Compared to the lower dose, the higher dose benefited FDG PET glucose uptake across multiple brain regions (P < .05), and the higher dose increased parietal and frontoparietal glutathione (P < .05). We did not demonstrate consistent blood level changes and cognitive scores did not improve. CONCLUSIONS: 1000 mg OAA, taken twice daily for 1 month, is safe in AD patients and engages brain energy metabolism.