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Literature DB >> 33422891

Dystrophic microglia are associated with neurodegenerative disease and not healthy aging in the human brain.

Ryan K Shahidehpour¹, Rebecca E Higdon¹, Nicole G Crawford¹, Janna H Neltner², Eseosa T Ighodaro³, Ela Patel⁴, Douglas Price⁴, Peter T Nelson⁵, Adam D Bachstetter⁶.

Abstract

Loss of physiological microglial function may increase the propagation of neurodegenerative diseases. Cellular senescence is a hallmark of aging; thus, we hypothesized age could be a cause of dystrophic microglia. Stereological counts were performed for total microglia, 2 microglia morphologies (hypertrophic and dystrophic) across the human lifespan. An age-associated increase in the number of dystrophic microglia was found in the hippocampus and frontal cortex. However, the increase in dystrophic microglia was proportional to the age-related increase in the total number of microglia. Thus, aging alone does not explain the presence of dystrophic microglia. We next tested if dystrophic microglia could be a disease-associated microglia morphology. Compared with controls, the number of dystrophic microglia was greater in cases with either Alzheimer's disease, dementia with Lewy bodies, or limbic-predominant age-related TDP-43 encephalopathy. These results demonstrate that microglia dystrophy, and not hypertrophic microglia, are the disease-associated microglia morphology. Finally, we found strong evidence for iron homeostasis changes in dystrophic microglia, providing a possible molecular mechanism driving the degeneration of microglia in neurodegenerative disease.

Entities: Chemical

Keywords: Aging; Microglia morphology; Neurodegeneration; Neuroinflammation; Neuropathology; Senescence

Mesh：

Substances：
Iron

Year: 2021 PMID： 33422891 PMCID： PMC8293930 DOI： 10.1016/j.neurobiolaging.2020.12.003

Source DB: PubMed Journal: Neurobiol Aging ISSN： 0197-4580 Impact factor: 4.673

35 in total

1. Microglial dystrophy in the aged and Alzheimer's disease brain is associated with ferritin immunoreactivity.

Authors: Kryslaine O Lopes; D Larry Sparks; Wolfgang J Streit
Journal: Glia Date: 2008-08-01 Impact factor: 7.452

2. Inhomogeneous distribution of Iba-1 characterizes microglial pathology in Alzheimer's disease.

Authors: Jasmin Tischer; Martin Krueger; Wolf Mueller; Ori Staszewski; Marco Prinz; Wolfgang J Streit; Ingo Bechmann
Journal: Glia Date: 2016-07-12 Impact factor: 7.452

Review 3. Cellular Senescence: Defining a Path Forward.

Authors: Vassilis Gorgoulis; Peter D Adams; Andrea Alimonti; Dorothy C Bennett; Oliver Bischof; Cleo Bishop; Judith Campisi; Manuel Collado; Konstantinos Evangelou; Gerardo Ferbeyre; Jesús Gil; Eiji Hara; Valery Krizhanovsky; Diana Jurk; Andrea B Maier; Masashi Narita; Laura Niedernhofer; João F Passos; Paul D Robbins; Clemens A Schmitt; John Sedivy; Konstantinos Vougas; Thomas von Zglinicki; Daohong Zhou; Manuel Serrano; Marco Demaria
Journal: Cell Date: 2019-10-31 Impact factor: 41.582

Review 4. Dystrophic microglia in late-onset Alzheimer's disease.

Authors: Wolfgang J Streit; Habibeh Khoshbouei; Ingo Bechmann
Journal: Glia Date: 2020-01-10 Impact factor: 7.452

5. Loss of ferritin-positive microglia relates to increased iron, RNA oxidation, and dystrophic microglia in the brains of aged male marmosets.

Authors: Juan de Dios Rodríguez-Callejas; Daniel Cuervo-Zanatta; Abraham Rosas-Arellano; Caroline Fonta; Eberhard Fuchs; Claudia Perez-Cruz
Journal: Am J Primatol Date: 2019-02-18 Impact factor: 2.371

6. Old age increases microglial senescence, exacerbates secondary neuroinflammation, and worsens neurological outcomes after acute traumatic brain injury in mice.

Authors: Rodney M Ritzel; Sarah J Doran; Ethan P Glaser; Victoria E Meadows; Alan I Faden; Bogdan A Stoica; David J Loane
Journal: Neurobiol Aging Date: 2019-02-20 Impact factor: 4.673

7. Increased oxidative stress, hyperphosphorylation of tau, and dystrophic microglia in the hippocampus of aged Tupaia belangeri.

Authors: Juan D Rodriguez-Callejas; Eberhard Fuchs; Claudia Perez-Cruz
Journal: Glia Date: 2020-02-25 Impact factor: 7.452

8. Single-cell transcriptomic analysis of Alzheimer's disease.

Authors: Hansruedi Mathys; Jose Davila-Velderrain; Zhuyu Peng; Fan Gao; Shahin Mohammadi; Jennie Z Young; Madhvi Menon; Liang He; Fatema Abdurrob; Xueqiao Jiang; Anthony J Martorell; Richard M Ransohoff; Brian P Hafler; David A Bennett; Manolis Kellis; Li-Huei Tsai
Journal: Nature Date: 2019-05-01 Impact factor: 49.962

9. Soluble phospho-tau from Alzheimer's disease hippocampus drives microglial degeneration.

Authors: Elisabeth Sanchez-Mejias; Victoria Navarro; Sebastian Jimenez; Maria Sanchez-Mico; Raquel Sanchez-Varo; Cristina Nuñez-Diaz; Laura Trujillo-Estrada; Jose Carlos Davila; Marisa Vizuete; Antonia Gutierrez; Javier Vitorica
Journal: Acta Neuropathol Date: 2016-10-14 Impact factor: 17.088

10. Dystrophic (senescent) rather than activated microglial cells are associated with tau pathology and likely precede neurodegeneration in Alzheimer's disease.

Authors: Wolfgang J Streit; Heiko Braak; Qing-Shan Xue; Ingo Bechmann
Journal: Acta Neuropathol Date: 2009-06-10 Impact factor: 17.088

26 in total

1. Type-I-interferon signaling drives microglial dysfunction and senescence in human iPSC models of Down syndrome and Alzheimer's disease.

Authors: Mengmeng Jin; Ranjie Xu; Le Wang; Mahabub Maraj Alam; Ziyuan Ma; Sining Zhu; Alessandra C Martini; Azadeh Jadali; Matteo Bernabucci; Ping Xie; Kelvin Y Kwan; Zhiping P Pang; Elizabeth Head; Ying Liu; Ronald P Hart; Peng Jiang
Journal: Cell Stem Cell Date: 2022-07-07 Impact factor: 25.269

2. SARS-CoV-2 Brain Regional Detection, Histopathology, Gene Expression, and Immunomodulatory Changes in Decedents with COVID-19.

Authors: Geidy E Serrano; Jessica E Walker; Cécilia Tremblay; Ignazio S Piras; Matthew J Huentelman; Christine M Belden; Danielle Goldfarb; David Shprecher; Alireza Atri; Charles H Adler; Holly A Shill; Erika Driver-Dunckley; Shyamal H Mehta; Richard Caselli; Bryan K Woodruff; Chadwick F Haarer; Thomas Ruhlen; Maria Torres; Steve Nguyen; Dasan Schmitt; Steven Z Rapscak; Christian Bime; Joseph L Peters; Ellie Alevritis; Richard A Arce; Michael J Glass; Daisy Vargas; Lucia I Sue; Anthony J Intorcia; Courtney M Nelson; Javon Oliver; Aryck Russell; Katsuko E Suszczewicz; Claryssa I Borja; Madison P Cline; Spencer J Hemmingsen; Sanaria Qiji; Holly M Hobgood; Joseph P Mizgerd; Malaya K Sahoo; Haiyu Zhang; Daniel Solis; Thomas J Montine; Gerald J Berry; Eric M Reiman; Katharina Röltgen; Scott D Boyd; Benjamin A Pinsky; James L Zehnder; Pierre Talbot; Marc Desforges; Michael DeTure; Dennis W Dickson; Thomas G Beach
Journal: J Neuropathol Exp Neurol Date: 2022-08-16 Impact factor: 3.148

Review 3. Microglia in Alzheimer's Disease: a Key Player in the Transition Between Homeostasis and Pathogenesis.

Authors: Karen N McFarland; Paramita Chakrabarty
Journal: Neurotherapeutics Date: 2022-03-14 Impact factor: 6.088

Review 4. Glycolytic metabolism supports microglia training during age-related neurodegeneration.

Authors: Alberto Camacho-Morales
Journal: Pharmacol Rep Date: 2022-04-03 Impact factor: 3.919

Review 5. Senescent Microglia: The Key to the Ageing Brain?

Authors: Eleanor K Greenwood; David R Brown
Journal: Int J Mol Sci Date: 2021-04-22 Impact factor: 5.923

6. Gestational and lactational exposure to 2,3,7,8-tetrachlorodibenzo-p-dioxin primes cortical microglia to tissue injury.

Authors: R L Lowery; S E Latchney; R P Peer; C E Lamantia; K A Lordy; L A Opanashuk; M McCall; A K Majewska
Journal: Brain Behav Immun Date: 2022-01-19 Impact factor: 7.217