Microglial senescence contributes to female-biased neuroinflammation in the aging mouse hippocampus: implications for Alzheimer's disease.
Journal
bioRxiv : the preprint server for biology
Titre abrégé: bioRxiv
Pays: United States
ID NLM: 101680187
Informations de publication
Date de publication:
01 Jun 2023
01 Jun 2023
Historique:
pubmed:
23
3
2023
medline:
23
3
2023
entrez:
22
3
2023
Statut:
epublish
Résumé
Microglia, the brain's principal immune cells, have been implicated in the pathogenesis of Alzheimer's disease (AD), a condition shown to affect more females than males. Although sex differences in microglial function and transcriptomic programming have been described across development and in disease models of AD, no studies have comprehensively identified the sex divergences that emerge in the aging mouse hippocampus. Further, existing models of AD generally develop pathology (amyloid plaques and tau tangles) early in life and fail to recapitulate the aged brain environment associated with late-onset AD. Here, we examined and compared transcriptomic and translatomic sex effects in young and old murine hippocampal microglia. Hippocampal tissue from C57BL6/N and microglial NuTRAP mice of both sexes were collected at young (5-6 month-old [mo]) and old (22-25 mo) ages. Cell sorting and affinity purification techniques were used to isolate the microglial transcriptome and translatome for RNA-sequencing and differential expression analyses. Flow cytometry, qPCR, and imaging approaches were used to confirm the transcriptomic and translatomic findings. There were marginal sex differences identified in the young hippocampal microglia, with most differentially expressed genes (DEGs) restricted to the sex chromosomes. Both sex chromosomally-and autosomally-encoded sex differences emerged with aging. These sex DEGs identified at old age were primarily female-biased and enriched in senescent and disease-associated microglial signatures. Normalized gene expression values can be accessed through a searchable web interface ( https://neuroepigenomics.omrf.org/ ). Pathway analyses identified upstream regulators induced to a greater extent in females than in males, including inflammatory mediators IFNG, TNF, and IL1B, as well as AD-risk genes TREM2 and APP. These data suggest that female microglia adopt disease-associated and senescent phenotypes in the aging mouse hippocampus, even in the absence of disease pathology, to a greater extent than males. This sexually divergent microglial phenotype may explain the difference in susceptibility and disease progression in the case of AD pathology. Future studies will need to explore sex differences in microglial heterogeneity in response to AD pathology and determine how sex-specific regulators (i.e., sex chromosomal or hormonal) elicit these sex effects.
Sections du résumé
Background
UNASSIGNED
Microglia, the brain's principal immune cells, have been implicated in the pathogenesis of Alzheimer's disease (AD), a condition shown to affect more females than males. Although sex differences in microglial function and transcriptomic programming have been described across development and in disease models of AD, no studies have comprehensively identified the sex divergences that emerge in the aging mouse hippocampus. Further, existing models of AD generally develop pathology (amyloid plaques and tau tangles) early in life and fail to recapitulate the aged brain environment associated with late-onset AD. Here, we examined and compared transcriptomic and translatomic sex effects in young and old murine hippocampal microglia.
Methods
UNASSIGNED
Hippocampal tissue from C57BL6/N and microglial NuTRAP mice of both sexes were collected at young (5-6 month-old [mo]) and old (22-25 mo) ages. Cell sorting and affinity purification techniques were used to isolate the microglial transcriptome and translatome for RNA-sequencing and differential expression analyses. Flow cytometry, qPCR, and imaging approaches were used to confirm the transcriptomic and translatomic findings.
Results
UNASSIGNED
There were marginal sex differences identified in the young hippocampal microglia, with most differentially expressed genes (DEGs) restricted to the sex chromosomes. Both sex chromosomally-and autosomally-encoded sex differences emerged with aging. These sex DEGs identified at old age were primarily female-biased and enriched in senescent and disease-associated microglial signatures. Normalized gene expression values can be accessed through a searchable web interface ( https://neuroepigenomics.omrf.org/ ). Pathway analyses identified upstream regulators induced to a greater extent in females than in males, including inflammatory mediators IFNG, TNF, and IL1B, as well as AD-risk genes TREM2 and APP.
Conclusions
UNASSIGNED
These data suggest that female microglia adopt disease-associated and senescent phenotypes in the aging mouse hippocampus, even in the absence of disease pathology, to a greater extent than males. This sexually divergent microglial phenotype may explain the difference in susceptibility and disease progression in the case of AD pathology. Future studies will need to explore sex differences in microglial heterogeneity in response to AD pathology and determine how sex-specific regulators (i.e., sex chromosomal or hormonal) elicit these sex effects.
Identifiants
pubmed: 36945656
doi: 10.1101/2023.03.07.531562
pmc: PMC10028852
pii:
doi:
Types de publication
Preprint
Langues
eng
Subventions
Organisme : NIA NIH HHS
ID : T32 AG052363
Pays : United States
Organisme : NIA NIH HHS
ID : F99 AG079813
Pays : United States
Organisme : NIA NIH HHS
ID : P30 AG050911
Pays : United States
Organisme : NIA NIH HHS
ID : R01 AG059430
Pays : United States
Organisme : NIA NIH HHS
ID : F31 AG064861
Pays : United States
Organisme : BLRD VA
ID : I01 BX003906
Pays : United States
Organisme : BLRD VA
ID : IK6 BX006033
Pays : United States
Organisme : NIH HHS
ID : DP5 OD033443
Pays : United States
Commentaires et corrections
Type : UpdateIn
Références
Curr Top Med Chem. 2009;9(7):599-610
pubmed: 19689368
Immunity. 2013 Jan 24;38(1):79-91
pubmed: 23273845
J Exp Med. 2018 Sep 3;215(9):2235-2245
pubmed: 30082275
J Neurosci Res. 2008 Apr;86(5):1087-95
pubmed: 17969104
Front Immunol. 2017 Sep 04;8:1075
pubmed: 28928743
J Neuroinflammation. 2017 Jul 21;14(1):141
pubmed: 28732515
J Neuroimmunol. 2005 May;162(1-2):89-96
pubmed: 15833363
J Gerontol A Biol Sci Med Sci. 2014 Jun;69 Suppl 1:S4-9
pubmed: 24833586
Nat Immunol. 2009 Jul;10(7):734-43
pubmed: 19503107
Sci Rep. 2022 Apr 29;12(1):7047
pubmed: 35487953
Nature. 2019 Apr;568(7751):187-192
pubmed: 30944478
Aging (Albany NY). 2013 Aug;5(8):590-1
pubmed: 23965734
Front Mol Neurosci. 2017 Aug 24;10:267
pubmed: 28970783
Cell. 2017 Jun 15;169(7):1276-1290.e17
pubmed: 28602351
J Exp Med. 2005 Feb 21;201(4):647-57
pubmed: 15728241
Immunity. 2019 Jan 15;50(1):253-271.e6
pubmed: 30471926
Cell Rep. 2019 Apr 23;27(4):1293-1306.e6
pubmed: 31018141
PLoS One. 2013 Sep 03;8(9):e74297
pubmed: 24019961
J Immunol. 2012 Feb 1;188(3):1098-107
pubmed: 22198949
J Neuroinflammation. 2021 Jul 19;18(1):162
pubmed: 34281564
Pharmacol Ther. 2017 Sep;177:81-95
pubmed: 28245991
BMC Neurol. 2021 Sep 16;21(1):358
pubmed: 34530748
Nat Immunol. 2011 Jun 05;12(7):624-30
pubmed: 21642987
Front Immunol. 2014 Sep 25;5:461
pubmed: 25309543
J Neuroimmunol. 2017 Oct 15;311:1-9
pubmed: 28863860
J Exp Med. 2016 May 2;213(5):667-75
pubmed: 27091843
Nature. 2007 Oct 11;449(7163):689-94
pubmed: 17851529
Eur J Biochem. 2001 May;268(9):2658-68
pubmed: 11322887
Immunity. 2017 Sep 19;47(3):566-581.e9
pubmed: 28930663
J Immunol. 2008 Nov 15;181(10):7254-62
pubmed: 18981147
EMBO J. 2008 Feb 6;27(3):499-508
pubmed: 18256700
Proc Natl Acad Sci U S A. 2022 Feb 22;119(8):
pubmed: 35177477
Handb Clin Neurol. 2020;175:261-273
pubmed: 33008530
Front Immunol. 2021 Jun 01;12:684430
pubmed: 34140954
Nat Neurosci. 2020 Feb;23(2):194-208
pubmed: 31959936
Sci Transl Med. 2020 Aug 26;12(558):
pubmed: 32848093
Nat Neurosci. 2013 Dec;16(12):1896-905
pubmed: 24162652
Aging Cell. 2022 Mar;21(3):e13565
pubmed: 35181976
Cell Rep. 2021 Jun 8;35(10):109228
pubmed: 34107254
Aging Cell. 2006 Apr;5(2):187-95
pubmed: 16626397
Proc Natl Acad Sci U S A. 2019 Mar 5;116(10):4637-4642
pubmed: 30782788
J Gerontol A Biol Sci Med Sci. 2014 Nov;69(11):1311-24
pubmed: 24994846
Cell Rep. 2013 Apr 25;3(4):1071-9
pubmed: 23545502
Nat Neurosci. 2023 Mar;26(3):406-415
pubmed: 36747024
Nat Rev Immunol. 2016 Oct;16(10):626-38
pubmed: 27546235
Biol Proced Online. 2011 Jan 31;13:3
pubmed: 21369534
Genes Immun. 2011 Sep;12(6):399-414
pubmed: 21490621
Alzheimers Res Ther. 2023 Jan 9;15(1):10
pubmed: 36624497
J Gerontol A Biol Sci Med Sci. 2023 Jun 1;78(6):938-943
pubmed: 36617879
N Engl J Med. 2023 Jan 5;388(1):9-21
pubmed: 36449413
Biochem Biophys Res Commun. 2003 Apr 11;303(3):800-7
pubmed: 12670482
F1000Res. 2016 Jun 20;5:1438
pubmed: 27508061
Bioinformatics. 2010 Jan 1;26(1):139-40
pubmed: 19910308
Nucleic Acids Res. 2019 May 7;47(8):e47
pubmed: 30783653
Exp Neurobiol. 2014 Jun;23(2):138-47
pubmed: 24963278
Proc Natl Acad Sci U S A. 2005 Oct 25;102(43):15545-50
pubmed: 16199517
Hum Mol Genet. 2015 May 15;24(10):2861-72
pubmed: 25666439
EMBO J. 2015 Jun 12;34(12):1612-29
pubmed: 25896511
Nat Commun. 2022 Aug 16;13(1):4827
pubmed: 35974106
Cell. 2022 Oct 27;185(22):4135-4152.e22
pubmed: 36257314
Aging (Albany NY). 2020 May 7;12(9):8221-8240
pubmed: 32379705
Am J Hum Genet. 2015 Aug 6;97(2):343-52
pubmed: 26235985
Aging Cell. 2017 Oct;16(5):1026-1034
pubmed: 28665028
Cell Rep. 2017 Jan 24;18(4):1048-1061
pubmed: 28122230
Mol Neurobiol. 2022 Aug;59(8):4669-4702
pubmed: 35589920
Sci Rep. 2021 Jul 22;11(1):14935
pubmed: 34294785
J Neurosci. 2015 Sep 9;35(36):12488-501
pubmed: 26354916
Neurobiol Dis. 2021 Jan;148:105217
pubmed: 33301878
J Gerontol A Biol Sci Med Sci. 2017 Jan;72(1):16-29
pubmed: 26786204
Geroscience. 2019 Oct;41(5):691-708
pubmed: 31493147
eNeuro. 2022 Mar 28;9(2):
pubmed: 35228310
Nat Neurosci. 2022 Mar;25(3):306-316
pubmed: 35260865
Cell Death Dis. 2019 Jul 19;10(8):555
pubmed: 31324751
Sci Signal. 2010 May 18;3(122):ra38
pubmed: 20484116
Commun Biol. 2020 Nov 19;3(1):693
pubmed: 33214681