Translational potential of JAX humanized‐APOE mice: sex differences in bioenergetic function in brain

Abstract

AbstractBackgroundThe preclinical phase of late onset Alzheimer’s disease (LOAD), known as the preclinical phase, can start 10 to 20 years prior to onset of clinical symptoms. Hypometabolism and impaired mitochondrial bioenergetics can emerge during prodromal phase as early indicators of AD risk. APOEe4, the greatest genetic risk factor for LOAD, is well documented to induce lipid metabolic dysregulation. We therefore sought to determine the impact of APOEe4. The following study analyzed body composition and mitochondrial functions to elucidate how the presence of APOEe4 in a mouse model contributes to bioenergetic changes, and whether they affect females and males equally.Method18mo old transgenic mouse models (JAX #029018 and #027894) carrying humanized APOE alleles (hAPOE3/3, hAPOE3/4 or hAPOE4/4) were assessed for fat and lean mass content via EchoMRI. A week later, fasting blood glucose levels were assessed prior to sacrifice, and brain tissues were collected to determine mitochondria function by Complex I and IV activity.ResultBody composition analyses indicated that hAPOEe4 males had significantly lower fat percentage than male APOEe3 mice. Females, irrespective of APOE genotype, exhibited significantly lower lean weight relative to males. No sex or APOE genotype difference was detected in fasting blood glucose plasma levels nor in mitochondrial Complex I activity. In contrast, mitochondrial Complex IV activity was significantly lower in females relative to males. Lastly, Complex IV activity was lower in mice exhibiting dominance aggressive behavior, specifically barbering, irrespective of sex or genotype.ConclusionAPOE mice resembling a human population of approximately 60 years of age displayed a sex difference in body composition parameters, where total and lean weight was higher in males than females. Sex differences also emerged in bioenergetic function, with females exhibiting lower mitochondria Complex IV activity relative to males. Sex differences are consistent with human data, whereas no genotype differences were observed and thus may influence the translational potential of the humanized APOE mouse model in LOAD research. However, the translational potential might be greater when linked with phenotypic characteristics.This work was supported by NIA grants R01AG057931, and RF1AG059093