Deficits in mitochondrial function and glucose metabolism seen in sporadic and familial Alzheimer’s disease derived Astrocytes are ameliorated by increasing hexokinase 1

Background

Astrocytes have multiple roles including providing neurons with metabolic substrates and maintaining neurotransmitters at neuronal synapses. Astrocyte glucose metabolism plays a key role in learning and memory with astrocytic glycogen a key substrate supporting memory encoding. The homeostatic role the astrocyte provides for neurons leads to metabolic demands, meaning that abnormalities in the function of astrocyte mitochondria and glycolysis could affect this relationship. Changes to cellular metabolism are seen early in Alzheimer’s disease (AD). Understanding cellular metabolism changes in AD astrocytes could be exploited as a new biomarker or synergistic therapeutic agent when combined with anti-amyloid treatments in AD.

Methods

In this project, we characterised mitochondrial and glycolytic dysfunction in astrocytes derived from patients with sporadic (n = 6) and familial (PSEN1, n = 3) AD, and associated controls (n = 9). Astrocytes were derived using direct reprogramming technology. Astrocyte metabolic outputs; ATP, and extracellular lactate levels were measured using luminescent and fluorescent protocols. Mitochondrial respiration and glycolytic function were measured using a Seahorse XF Analyzer. Hexokinase deficits identified where corrected by transfecting astrocytes with an adenovirus viral vector containing the hexokinase 1 gene.

Results

In sAD astrocytes a 20% reduction (p = 0.05) and in fAD a 48% (p<0.01) reduction in total cellular ATP was seen. A 44% reduction (p<0.05), and 80% reduction in Mitochondrial spare capacity was seen in sAD and fAD respectively. Reactive oxygen species (ROS) where increased in both AD astrocyte types (p = 0.05). Mitochondrial complex I and II was significantly increased in sAD (p<0.05) but not in fAD. Astrocyte glycolytic reserve and extracellular lactate was significantly reduced when compared to controls in both sAD and fAD (p<0.05). We identified that astrocytes had a deficit in the glycolytic pathway enzyme hexokinase, and that correcting this deficit restored total cellular ATP levels, extracellular lactate and reduced ROS in sAD but not fAD astrocytes.

Conclusion

AD astrocytes have abnormalities in functional capacity of mitochondria and the process of glycolysis. These deficits are likely to impede metabolic support for neurons. These functional deficits can be improved by correcting hexokinase deficits. This suggests that hexokinase 1 deficiency could potentially be exploited as a new therapeutic target for AD.