Your search keyword '"Alaina M. Reagan"' showing total 2 results

1. Plcg2M28L interacts with high fat-high sugar diet to accelerate Alzheimer’s disease-relevant phenotypes in mice

Author

Adrian L. Oblak, Kevin P. Kotredes, Ravi Pandey, Alaina M. Reagan, Cynthia Ingraham, Bridget Perkins, Chris Lloyd, Deborah Baker, Peter B. Lin, Disha M. Soni, Andy Tsai, Scott C. Persohn, Amanda A Bedwell, Kierra Eldridge, Rachael Speedy, Jill A. Meyers, Johnathon Peters, Lucas L. Figueiredo, Michael Sasner, Paul R. Territo, Stacey J. Sukoff Rizzo, Gregory W. Carter, Bruce T. Lamb, and Gareth R. Howell

Abstract

Obesity is recognized as a significant risk factor for Alzheimer’s disease (AD). Studies have supported the notion that obesity accelerates AD-related pathophysiology in mouse models of AD. The majority of studies to date have focused on the use of early-onset AD models. Here we evaluate the impact of genetic risk factors on late-onset AD (LOAD) in mice fed a high fat/high sugar diet. We focused on three mouse models created through the IU/JAX/Pitt MODEL-AD Center, LOAD1, LOAD1.Plcg2M28L and LOAD1.Mthfr677C>T. At 2 months of age, animals were placed on a high fat/high sugar diet (HFD) that induces obesity, or a control diet (CD) that does not, until 12 months of age. Throughout the study, blood was collected to assess cholesterol and glucose. Positron emission tomography/computed tomography (PET/CT) was completed prior to sacrifice to image for glucose utilization and brain perfusion. At the completion of the study, blood and brains were collected for analysis. As expected, animals fed the HFD, regardless of genotype or sex, showed a significant increase in body weight compared to those fed the CD. Glucose and cholesterol increased as a function of HFD as well. Interestingly, LOAD1.Plcg2M28L demonstrated an increase in microglia density as well as alterations in regional brain glucose and perfusion when on a HFD. These changes were not observed in LOAD1 or LOAD1.Mthfr677C>T animals when fed a HFD. Furthermore, LOAD1.Plcg2M28L but not LOAD1.Mthfr677C>T or LOAD1 animals showed transcriptomics correlations to human AD modules. Our results show HFD affects brain health in a genotype-specific manner. Further insight into this process may have significant implications in the development of lifestyle interventions for treatment of AD.

Published

2022

2. The 677C>T variant in methylenetetrahydrofolate reductase causes morphological and functional cerebrovascular deficits in mice

Author

Alaina M. Reagan, Karen E. Christensen, Leah C. Graham, Amanda A. Bedwell, Kierra Eldridge, Rachael Speedy, Lucas L. Figueiredo, Scott C. Persohn, Teodoro Bottiglieri, Michael Sasner, Paul R. Territo, Rima Rozen, and Gareth R. Howell

Subjects

digestive system diseases

Abstract

Vascular contributions to cognitive impairment and dementia (VCID) particularly Alzheimer’s disease and related dementias (ADRDs) are increasing; however, mechanisms driving cerebrovascular decline are poorly understood. Methylenetetrahydrofolate reductase (MTHFR) is a critical enzyme in the folate and methionine cycles. Variants in MTHFR, notably 677C>T, are associated with dementias, but no mouse model existed to identify mechanisms by which MTHFR677C>T increases risk. Therefore, MODEL-AD created a novel knock-in (KI) strain carrying the Mthfr677C>T allele on the C57BL/6J background (Mthfr677C>T) to characterize morphology and function perturbed by the variant. Consistent with human clinical data, Mthfr677C>T mice have reduced enzyme activity in the liver and elevated plasma homocysteine levels. MTHFR enzyme activity as well as critical metabolites in the folate and methionine cycles are reduced in the Mthfr677C>T brain. Mice showed reduced tissue perfusion in numerous brain regions by PET/CT as well as significantly reduced vascular density and increased GFAP-expressing astrocytes in frontal cortex. Electron microscopy revealed cerebrovascular damage including endothelial and pericyte apoptosis, reduced luminal size, and increased astrocyte and microglial presence in the microenvironment. Collectively, these data suggest critical perturbations to cerebrovascular function in Mthfr677C>T mice supporting its use as a model for preclinical studies of VCID.

Published

2021