Microglia senescence occurs in both substantia nigra and ventral tegmental area.
Fatemeh ShaerzadehLeah PhanDouglas MillerMaxwell DacquelWilliam HachmeisterCarissa HansenAlexandra BechtleDuan TuMaia MartchevaThomas C FosterAshok KumarWolfgang J StreitHabibeh KhoshboueiPublished in: Glia (2020)
During aging humans lose midbrain dopamine neurons, but not all dopamine regions exhibit vulnerability to neurodegeneration. Microglia maintain tissue homeostasis and neuronal support, but microglia become senescent and likely lose some of their functional abilities. Since aging is the greatest risk factor for Parkinson's disease, we hypothesized that aging-related changes in microglia and neurons occur in the vulnerable substantia nigra pars compacta (SNc) but not the ventral tegmental area (VTA). We conducted stereological analyses to enumerate microglia and dopaminergic neurons in the SNc and VTA of 1-, 6-, 9-, 18-, and 24-month-old C57BL/J6 mice using sections double-stained with tyrosine hydroxylase (TH) and Iba1. Both brain regions show an increase in microglia with aging, whereas numbers of TH+ cells show no significant change after 9 months of age in SNc and 6 months in VTA. Morphometric analyses reveal reduced microglial complexity and projection area while cell body size increases with aging. Contact sites between microglia and dopaminergic neurons in both regions increase with aging, suggesting increased microglial support/surveillance of dopamine neurons. To assess neurotrophin expression in dopaminergic neurons, BDNF and TH mRNA were quantified. Results show that the ratio of BDNF to TH decreases in the SNc, but not the VTA. Gait analysis indicates subtle, aging-dependent changes in gait indices. In conclusion, increases in microglial cell number, ratio of microglia to dopamine neurons, and contact sites suggest that innate biological mechanisms compensate for the aging-dependent decline in microglia morphological complexity (senescence) to ensure continued neuronal support in the SNc and VTA.
Keyphrases
- neuropathic pain
- spinal cord
- inflammatory response
- spinal cord injury
- lipopolysaccharide induced
- lps induced
- uric acid
- single cell
- immune response
- public health
- induced apoptosis
- poor prognosis
- stress induced
- magnetic resonance imaging
- type diabetes
- genome wide
- deep brain stimulation
- binding protein
- mesenchymal stem cells
- bone marrow
- gene expression
- stem cells
- blood brain barrier
- signaling pathway
- long non coding rna
- magnetic resonance
- computed tomography
- cell death
- endoplasmic reticulum stress