New research from the University of Eastern Finland explores the role of diabetes in the cellular and molecular changes underlying Alzheimer's disease (AD). In an AD mouse model, diabetes induced through a diet rich in fats and sugars weakened the accumulation of microglial cells around amyloid plaques and increased the formation of neuritic plaques with prominent tau pathology. Besides the mouse model, a similar observation was also made in hydrocephalus patients with type 2 diabetes, who had fewer microglia around amyloid plaques than patients without diabetes. The findings provide valuable new insight into the cellular mechanisms by which type 2 diabetes contributes to the risk and development of AD.
Alzheimer’s disease is the most common form of dementia, with no cure to date. AD is characterised by the accumulation of beta-amyloid peptides and phosphorylated tau proteins in the brain, leading to the activation of the immune cells in brain: microglia and astrocytes. AD also causes damage to axons and dendrites and, ultimately, leads to neuronal cell death. Recent genetic studies suggest that microglia play a key role in the development of AD. In addition to genetics, environmental and lifestyle factors, and diseases associated with them, such as type 2 diabetes, affect the risk of AD. Type 2 diabetes has long been known to increase the risk of AD and to influence the disease course, but the underlying cellular and molecular events are still elusive.
In the new study, transgenic AD model mice were put on a six-month regimen resembling the typical Western diet, i.e. one that is rich in fats and sugars, and this led to the development of diabetes in the mice. In behavioural analysis, diabetic mice showed impaired learning and memory compared to mice on standard diet. Bulk RNA expression analysis of brain samples of the mice suggested weakened response of microglial cells to amyloid-β, as well as attenuation of Trem2 and PI3K-Akt signalling pathways. Immunohistochemical analyses of entorhinal and hippocampal brain sections supported these findings, as the diabetic mice had fewer microglia and more dystrophic neurites around amyloid plaques than mice on the standard diet.
“This study sheds new light on the cellular level how diabetes contributes to the development of AD, and specifically highlights the importance of brain immune cells in the disease process. Our findings suggest that diabetes can weaken the ability of microglia to react to harmful amyloid-β. It seems that diabetes can lead to the formation of neuritic plaques, which are characteristic pathological changes in the AD brain,” Senior Researcher Teemu Natunen from the Institute of Biomedicine at the University of Eastern Finland says.
Western diet did not associate with the overall accumulation of amyloid-β in the brain of AD mice.
“A diet that is rich in fat and sugar, i.e. the typical Western diet, is known to increase the risk of type 2 diabetes, and this way, it possibly also contributes to the development of AD,” Professor Heikki Tanila from the A. I. Virtanen Institute for Molecular Sciences at the University of Eastern Finland says.
The researchers further analysed cortical biopsies of idiopathic normal pressure hydrocephalus patients, collected and studied by Professor Ville Leinonen’s research group at Kuopio University Hospital. Human cortical samples showed changes that were similar to those observed in mice: in normal pressure hydrocephalus patients with type 2 diabetes, the number of microglia around amyloid plaques was lower than in non-diabetic patients.
“The set of data from patients with normal pressure hydrocephalus constituted an important part of our study, because it allowed us to show that also humans with type 2 diabetes have an impaired microglia response. This type of collaboration between research groups at the University of Eastern Finland and Kuopio University Hospital, which makes it possible for us to verify findings from basic research in patient samples, is crucial for the high-level research carried out in the Neuroscience Research Community at UEF,” Professor Mikko Hiltunen from the Institute of Biomedicine at the University of Eastern Finland says.
The study was funded by the Academy of Finland, the JPND EU Cofund programme, and Sigrid Jusélius Foundation. The study was published in Molecular Neurodegeneration.
For further information, please contact:
Senior Researcher Teemu Natunen, tel. +358 50 3871272, teemu.natunen (at) uef.fi, Institute of Biomedicine, University of Eastern Finland, Kuopio
Professor Heikki Tanila, tel. +358 40 3552084, heikki.tanila (at) uef.fi, A.I, Virtanen Institute for Molecular Sciences, University of Eastern Finland, Kuopio
Professor Ville Leinonen, tel. +358 44-717 2303, ville.leinonen (at) uef.fi, Institute of Clinical Medicine - Neurosurgery, University of Eastern Finland and Kuopio University Hospital
Professor Mikko Hiltunen, tel. +358 40 3552014, mikko.hiltunen (at) uef.fi, Institute of Biomedicine, University of Eastern Finland, Kuopio
Natunen T*, Martiskainen H*, Marttinen M*, Gabbouj S, Koivisto H, Kemppainen S, Kaipainen S, Takalo M, Svobodová H, Leppänen L, Kemiläinen B, Ryhänen S, Kuulasmaa T, Rahunen E, Juutinen S, Mäkinen P, Miettinen P, Rauramaa T, Pihlajamäki J, Haapasalo A, Leinonen V, Tanila H*, Hiltunen M*. Diabetic phenotype in mouse and humans reduces the number of microglia around β-amyloid plaques. Molecular Neurodegeneration 2020;15(1):66. DOI: 10.1186/s13024-020-00415-2