Literature DB >> 33301878

Alzheimer's-associated PU.1 expression levels regulate microglial inflammatory response.

Anna A Pimenova1, Manon Herbinet2, Ishaan Gupta3, Saima I Machlovi1, Kathryn R Bowles1, Edoardo Marcora4, Alison M Goate5.   

Abstract

More than forty loci contribute to genetic risk for Alzheimer's disease (AD). These risk alleles are enriched in myeloid cell enhancers suggesting that microglia, the brain-resident macrophages, contribute to AD risk. We have previously identified SPI1/PU.1, a master regulator of myeloid cell development in the brain and periphery, as a genetic risk factor for AD. Higher expression of SPI1 is associated with increased risk for AD, while lower expression is protective. To investigate the molecular and cellular phenotypes associated with higher and lower expression of PU.1 in microglia, we used stable overexpression and knock-down of PU.1 in BV2, an immortalized mouse microglial cell line. Transcriptome analysis suggests that reduced PU.1 expression suppresses expression of homeostatic genes similar to the disease-associated microglia response to amyloid plaques in mouse models of AD. Moreover, PU.1 knock-down resulted in activation of protein translation, antioxidant action and cholesterol/lipid metabolism pathways with a concomitant decrease of pro-inflammatory gene expression. PU.1 overexpression upregulated and knock-down downregulated phagocytic uptake in BV2 cells independent of the nature of the engulfed material. However, cells with reduced PU.1 expression retained their ability to internalize myelin similar to control albeit with a delay, which aligns with their anti-inflammatory profile. Here we identified several microglial responses that are modulated by PU.1 expression levels and propose that risk association of PU.1 to AD is driven by increased pro-inflammatory response due to increased viability of cells under cytotoxic conditions. In contrast, low expression of PU.1 leads to increased cell death under cytotoxic conditions accompanied by reduced pro-inflammatory signaling that decreased A1 reactive astrocytes signature supporting the protective effect of SPI1 genotype in AD. These findings inform future in vivo validation studies and design of small molecule screens for therapeutic discovery in AD.
Copyright © 2020. Published by Elsevier Inc.

Entities:  

Keywords:  Alzheimer's disease; Amyloid β; Anti-inflammatory microglia; Disease-associated microglia; PU.1; Phagocytosis

Mesh:

Substances:

Year:  2020        PMID: 33301878      PMCID: PMC7808757          DOI: 10.1016/j.nbd.2020.105217

Source DB:  PubMed          Journal:  Neurobiol Dis        ISSN: 0969-9961            Impact factor:   5.996


  62 in total

1.  TREM2 regulates microglial cell activation in response to demyelination in vivo.

Authors:  Claudia Cantoni; Bryan Bollman; Danilo Licastro; Mingqiang Xie; Robert Mikesell; Robert Schmidt; Carla M Yuede; Daniela Galimberti; Gunilla Olivecrona; Robyn S Klein; Anne H Cross; Karel Otero; Laura Piccio
Journal:  Acta Neuropathol       Date:  2015-01-29       Impact factor: 17.088

2.  Alzheimer's disease risk gene CD33 inhibits microglial uptake of amyloid beta.

Authors:  Ana Griciuc; Alberto Serrano-Pozo; Antonio R Parrado; Andrea N Lesinski; Caroline N Asselin; Kristina Mullin; Basavaraj Hooli; Se Hoon Choi; Bradley T Hyman; Rudolph E Tanzi
Journal:  Neuron       Date:  2013-04-25       Impact factor: 17.173

3.  A Tale of Two Genes: Microglial Apoe and Trem2.

Authors:  Anna A Pimenova; Edoardo Marcora; Alison M Goate
Journal:  Immunity       Date:  2017-09-19       Impact factor: 31.745

4.  Lipid-Associated Macrophages Control Metabolic Homeostasis in a Trem2-Dependent Manner.

Authors:  Diego Adhemar Jaitin; Lorenz Adlung; Christoph A Thaiss; Assaf Weiner; Baoguo Li; Hélène Descamps; Patrick Lundgren; Camille Bleriot; Zhaoyuan Liu; Aleksandra Deczkowska; Hadas Keren-Shaul; Eyal David; Niv Zmora; Shai Meron Eldar; Nir Lubezky; Oren Shibolet; David A Hill; Mitchell A Lazar; Marco Colonna; Florent Ginhoux; Hagit Shapiro; Eran Elinav; Ido Amit
Journal:  Cell       Date:  2019-06-27       Impact factor: 41.582

5.  Diverse Brain Myeloid Expression Profiles Reveal Distinct Microglial Activation States and Aspects of Alzheimer's Disease Not Evident in Mouse Models.

Authors:  Brad A Friedman; Karpagam Srinivasan; Gai Ayalon; William J Meilandt; Han Lin; Melanie A Huntley; Yi Cao; Seung-Hye Lee; Patrick C G Haddick; Hai Ngu; Zora Modrusan; Jessica L Larson; Joshua S Kaminker; Marcel P van der Brug; David V Hansen
Journal:  Cell Rep       Date:  2018-01-16       Impact factor: 9.423

6.  Microglia constitute a barrier that prevents neurotoxic protofibrillar Aβ42 hotspots around plaques.

Authors:  Carlo Condello; Peng Yuan; Aaron Schain; Jaime Grutzendler
Journal:  Nat Commun       Date:  2015-01-29       Impact factor: 14.919

7.  Fragmented mitochondria released from microglia trigger A1 astrocytic response and propagate inflammatory neurodegeneration.

Authors:  Amit U Joshi; Paras S Minhas; Shane A Liddelow; Bereketeab Haileselassie; Katrin I Andreasson; Gerald W Dorn; Daria Mochly-Rosen
Journal:  Nat Neurosci       Date:  2019-09-23       Impact factor: 24.884

8.  A Comprehensive Resource for Induced Pluripotent Stem Cells from Patients with Primary Tauopathies.

Authors:  Celeste M Karch; Aimee W Kao; Anna Karydas; Khadijah Onanuga; Rita Martinez; Andrea Argouarch; Chao Wang; Cindy Huang; Peter Dongmin Sohn; Kathryn R Bowles; Salvatore Spina; M Catarina Silva; Jacob A Marsh; Simon Hsu; Derian A Pugh; Nupur Ghoshal; Joanne Norton; Yadong Huang; Suzee E Lee; William W Seeley; Panagiotis Theofilas; Lea T Grinberg; Fermin Moreno; Kathryn McIlroy; Bradley F Boeve; Nigel J Cairns; John F Crary; Stephen J Haggarty; Justin K Ichida; Kenneth S Kosik; Bruce L Miller; Li Gan; Alison M Goate; Sally Temple
Journal:  Stem Cell Reports       Date:  2019-10-17       Impact factor: 7.294

9.  Meta-analysis of 74,046 individuals identifies 11 new susceptibility loci for Alzheimer's disease.

Authors:  J C Lambert; C A Ibrahim-Verbaas; D Harold; A C Naj; R Sims; C Bellenguez; A L DeStafano; J C Bis; G W Beecham; B Grenier-Boley; G Russo; T A Thorton-Wells; N Jones; A V Smith; V Chouraki; C Thomas; M A Ikram; D Zelenika; B N Vardarajan; Y Kamatani; C F Lin; A Gerrish; H Schmidt; B Kunkle; M L Dunstan; A Ruiz; M T Bihoreau; S H Choi; C Reitz; F Pasquier; C Cruchaga; D Craig; N Amin; C Berr; O L Lopez; P L De Jager; V Deramecourt; J A Johnston; D Evans; S Lovestone; L Letenneur; F J Morón; D C Rubinsztein; G Eiriksdottir; K Sleegers; A M Goate; N Fiévet; M W Huentelman; M Gill; K Brown; M I Kamboh; L Keller; P Barberger-Gateau; B McGuiness; E B Larson; R Green; A J Myers; C Dufouil; S Todd; D Wallon; S Love; E Rogaeva; J Gallacher; P St George-Hyslop; J Clarimon; A Lleo; A Bayer; D W Tsuang; L Yu; M Tsolaki; P Bossù; G Spalletta; P Proitsi; J Collinge; S Sorbi; F Sanchez-Garcia; N C Fox; J Hardy; M C Deniz Naranjo; P Bosco; R Clarke; C Brayne; D Galimberti; M Mancuso; F Matthews; S Moebus; P Mecocci; M Del Zompo; W Maier; H Hampel; A Pilotto; M Bullido; F Panza; P Caffarra; B Nacmias; J R Gilbert; M Mayhaus; L Lannefelt; H Hakonarson; S Pichler; M M Carrasquillo; M Ingelsson; D Beekly; V Alvarez; F Zou; O Valladares; S G Younkin; E Coto; K L Hamilton-Nelson; W Gu; C Razquin; P Pastor; I Mateo; M J Owen; K M Faber; P V Jonsson; O Combarros; M C O'Donovan; L B Cantwell; H Soininen; D Blacker; S Mead; T H Mosley; D A Bennett; T B Harris; L Fratiglioni; C Holmes; R F de Bruijn; P Passmore; T J Montine; K Bettens; J I Rotter; A Brice; K Morgan; T M Foroud; W A Kukull; D Hannequin; J F Powell; M A Nalls; K Ritchie; K L Lunetta; J S Kauwe; E Boerwinkle; M Riemenschneider; M Boada; M Hiltuenen; E R Martin; R Schmidt; D Rujescu; L S Wang; J F Dartigues; R Mayeux; C Tzourio; A Hofman; M M Nöthen; C Graff; B M Psaty; L Jones; J L Haines; P A Holmans; M Lathrop; M A Pericak-Vance; L J Launer; L A Farrer; C M van Duijn; C Van Broeckhoven; V Moskvina; S Seshadri; J Williams; G D Schellenberg; P Amouyel
Journal:  Nat Genet       Date:  2013-10-27       Impact factor: 38.330

10.  Elimination of Microglia Improves Functional Outcomes Following Extensive Neuronal Loss in the Hippocampus.

Authors:  Rachel A Rice; Elizabeth E Spangenberg; Hana Yamate-Morgan; Rafael J Lee; Rajan P S Arora; Michael X Hernandez; Andrea J Tenner; Brian L West; Kim N Green
Journal:  J Neurosci       Date:  2015-07-08       Impact factor: 6.167
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  13 in total

1.  Genetics of the human microglia regulome refines Alzheimer's disease risk loci.

Authors:  Roman Kosoy; John F Fullard; Biao Zeng; Jaroslav Bendl; Pengfei Dong; Samir Rahman; Steven P Kleopoulos; Zhiping Shao; Kiran Girdhar; Jack Humphrey; Katia de Paiva Lopes; Alexander W Charney; Brian H Kopell; Towfique Raj; David Bennett; Christopher P Kellner; Vahram Haroutunian; Gabriel E Hoffman; Panos Roussos
Journal:  Nat Genet       Date:  2022-08-05       Impact factor: 41.307

Review 2.  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

3.  TREM2 regulates purinergic receptor-mediated calcium signaling and motility in human iPSC-derived microglia.

Authors:  Amit Jairaman; Amanda McQuade; Alberto Granzotto; You Jung Kang; Jean Paul Chadarevian; Sunil Gandhi; Ian Parker; Ian Smith; Hansang Cho; Stefano L Sensi; Shivashankar Othy; Mathew Blurton-Jones; Michael D Cahalan
Journal:  Elife       Date:  2022-02-22       Impact factor: 8.713

Review 4.  APOE mediated neuroinflammation and neurodegeneration in Alzheimer's disease.

Authors:  Samira Parhizkar; David M Holtzman
Journal:  Semin Immunol       Date:  2022-02-26       Impact factor: 10.671

Review 5.  Genomics of Alzheimer's disease implicates the innate and adaptive immune systems.

Authors:  Yihan Li; Simon M Laws; Luke A Miles; James S Wiley; Xin Huang; Colin L Masters; Ben J Gu
Journal:  Cell Mol Life Sci       Date:  2021-10-27       Impact factor: 9.207

Review 6.  Functional insight into LOAD-associated microglial response genes.

Authors:  Lauren A Jonas; Tanya Jain; Yue-Ming Li
Journal:  Open Biol       Date:  2022-01-26       Impact factor: 7.124

7.  MicroRNA-124 Alleviates Retinal Vasoregression via Regulating Microglial Polarization.

Authors:  Ying Chen; Jihong Lin; Andrea Schlotterer; Luke Kurowski; Sigrid Hoffmann; Seddik Hammad; Steven Dooley; Malte Buchholz; Jiong Hu; Ingrid Fleming; Hans-Peter Hammes
Journal:  Int J Mol Sci       Date:  2021-10-14       Impact factor: 5.923

8.  Bioinformatics pipeline to guide late-onset Alzheimer's disease (LOAD) post-GWAS studies: Prioritizing transcription regulatory variants within LOAD-associated regions.

Authors:  Michael W Lutz; Ornit Chiba-Falek
Journal:  Alzheimers Dement (N Y)       Date:  2022-02-23

9.  Association of SPI1 Haplotypes with Altered SPI1 Gene Expression and Alzheimer's Disease Risk.

Authors:  Han Cao; Xiaopu Zhou; Yu Chen; Fanny C F Ip; Yuewen Chen; Nicole C H Lai; Ronnie M N Lo; Estella P S Tong; Vincent C T Mok; Timothy C Y Kwok; Amy K Y Fu; Nancy Y Ip
Journal:  J Alzheimers Dis       Date:  2022       Impact factor: 4.160

10.  Modest changes in Spi1 dosage reveal the potential for altered microglial function as seen in Alzheimer's disease.

Authors:  Ruth E Jones; Robert Andrews; Peter Holmans; Matthew Hill; Philip R Taylor
Journal:  Sci Rep       Date:  2021-07-22       Impact factor: 4.379
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