Trained immunity induced by high-salt diet impedes stroke recovery

被引:13
作者
Lin, Tze-Yen [1 ]
Jiang, Danye [2 ]
Chen, Wan-Ru [1 ,3 ]
Lin, Jhih Syuan [1 ]
Zhang, Xin-Yu [1 ]
Chen, Chih-Hung [1 ]
Hsu, Chia-Lang [4 ]
Lai, Liang-Chuan [1 ]
Chen, Ping-Hung [5 ]
Yang, Kai-Chien [6 ]
Sansing, Lauren H. [7 ]
Chang, Che-Feng [1 ]
机构
[1] Natl Taiwan Univ, Coll Med, Dept & Grad Inst Physiol, Taipei, Taiwan
[2] Univ Texas Hlth Sci Ctr Houston, McGovern Med Sch, Dept Neurol, Houston, TX USA
[3] Natl Taiwan Univ, Coll Med, Sch Med, Taipei, Taiwan
[4] Natl Taiwan Univ Hosp, Dept Med Res, Taipei, Taiwan
[5] Natl Taiwan Univ, Coll Med, Dept & Grad Inst Biochem & Mol Biol, Taipei, Taiwan
[6] Natl Taiwan Univ, Coll Med, Dept & Grad Inst Pharmacol, Taipei, Taiwan
[7] Yale Univ, Sch Med, Dept Neurol, New Haven, CT USA
来源
EMBO REPORTS | 2023年 / 24卷 / 12期
关键词
high-salt diet; intracerebral hemorrhage; macrophages; nr4a1; trained immunity; INTRACEREBRAL HEMORRHAGE; HEMATOMA RESOLUTION; NR4A1; CELLS; MACROPHAGES; ACTIVATION; INDUCTION; HYPERTENSION; CONTRIBUTES; DYSFUNCTION;
D O I
10.15252/embr.202357164
中图分类号
Q5 [生物化学]; Q7 [分子生物学];
学科分类号
071010 ; 081704 ;
摘要
A high-salt diet (HSD) elicits sustained sterile inflammation and worsens tissue injury. However, how this occurs after stroke, a leading cause of morbidity and mortality, remains unknown. Here, we report that HSD impairs long-term brain recovery after intracerebral hemorrhage, a severe form of stroke, despite salt withdrawal prior to the injury. Mechanistically, HSD induces innate immune priming and training in hematopoietic stem and progenitor cells (HSPCs) by downregulation of NR4a family and mitochondrial oxidative phosphorylation. This training compromises alternative activation of monocyte-derived macrophages (MDMs) without altering the initial inflammatory responses of the stroke brain. Healthy mice transplanted with bone marrow from HSD-fed mice retain signatures of reduced MDM reparative functions, further confirming a persistent form of innate immune memory that originates in the bone marrow. Loss of NR4a1 in macrophages recapitulates HSD-induced negative impacts on stroke outcomes while gain of NR4a1 enables stroke recovery in HSD animals. Together, we provide the first evidence that links HSD-induced innate immune memory to the acquisition of persistent dysregulated inflammatory responses and unveils NR4a1 as a potential therapeutic target. imageHigh-salt intake induces trained immunity through metabolic reprogramming and downregulation of NR4a nuclear receptors. Trained monocyte-derived macrophages reduce reparative activities in the stroke brain, and consequently, hematoma clearance, brain repair, and functional recovery are impaired.Excessive dietary salt intake impedes long-term stroke recovery even after high-salt withdrawal prior to injury.High-salt intake triggers immunological priming and training of bone marrow progenitor cells.The trained property is retained, which leads to diminished reparative macrophage polarization in the stroke brain.Pharmacological activation of NR4a1 by celastrol treatment rescues the adverse effects induced by high-salt diet. High-salt intake induces trained immunity through metabolic reprogramming and downregulation of NR4a nuclear receptors. Trained monocyte-derived macrophages reduce reparative activities in the stroke brain, and consequently, hematoma clearance, brain repair, and functional recovery are impaired.image
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页数:22
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共 76 条
[1]   Health effects of dietary risks in 195 countries, 1990-2017: a systematic analysis for the Global Burden of Disease Study 2017 [J].
Afshin, Ashkan ;
Sur, Patrick John ;
Fay, Kairsten A. ;
Cornaby, Leslie ;
Ferrara, Giannina ;
Salama, Joseph S. ;
Mullany, Erin C. ;
Abate, Kalkidan Hassen ;
Abbafati, Cristiana ;
Abebe, Zegeye ;
Afarideh, Mohsen ;
Aggarwal, Anju ;
Agrawal, Sutapa ;
Akinyemiju, Tomi ;
Alahdab, Fares ;
Bacha, Umar ;
Bachman, Victoria F. ;
Badali, Hamid ;
Badawi, Alaa ;
Bensenor, Isabela M. ;
Bernabe, Eduardo ;
Biryukov, Stan H. ;
Biadgilign, Sibhatu Kassa K. ;
Cahill, Leah E. ;
Carrero, Juan J. ;
Cercy, Kelly M. ;
Dandona, Lalit ;
Dandona, Rakhi ;
Anh Kim Dang ;
Degefa, Meaza Girma ;
Zaki, Maysaa El Sayed ;
Esteghamati, Alireza ;
Esteghamati, Sadaf ;
Fanzo, Jessica ;
Farinha, Carla Sofia E. Sa ;
Farvid, Maryam S. ;
Farzadfar, Farshad ;
Feigin, Valery L. ;
Fernandes, Joao C. ;
Flor, Luisa Sorio ;
Foigt, Nataliya A. ;
Forouzanfar, Mohammad H. ;
Ganji, Morsaleh ;
Geleijnse, Johanna M. ;
Gillum, Richard F. ;
Goulart, Alessandra C. ;
Grosso, Giuseppe ;
Guessous, Idris ;
Hamidi, Samer ;
Hankey, Graeme J. .
LANCET, 2019, 393 (10184) :1958-1972
[2]  
Amara Suneetha, 2016, Biochem Biophys Rep, V7, P1
[3]   Longitudinal transcriptomics define the stages of myeloid activation in the living human brain after intracerebral hemorrhage [J].
Askenase, Michael H. ;
Goods, Brittany A. ;
Beatty, Hannah E. ;
Steinschneider, Arthur F. ;
Velazquez, Sofia E. ;
Osherov, Artem ;
Landreneau, Margaret J. ;
Carroll, Shaina L. ;
Tran, Tho B. ;
Avram, Victor S. ;
Drake, Riley S. ;
Gatter, G. James ;
Massey, Jordan A. ;
Karuppagounder, Saravanan S. ;
Ratan, Rajiv R. ;
Matouk, Charles C. ;
Sheth, Kevin N. ;
Ziai, Wendy C. ;
Parry-Jones, Adrian R. ;
Awad, Issam A. ;
Zuccarello, Mario ;
Thompson, Richard E. ;
Dawson, Jesse ;
Hanley, Daniel F. ;
Love, J. Christopher ;
Shalek, Alex K. ;
Sansing, Lauren H. .
SCIENCE IMMUNOLOGY, 2021, 6 (56)
[4]   Heatmapper: web-enabled heat mapping for all [J].
Babicki, Sasha ;
Arndt, David ;
Marcu, Ana ;
Liang, Yongjie ;
Grant, Jason R. ;
Maciejewski, Adam ;
Wishart, David S. .
NUCLEIC ACIDS RESEARCH, 2016, 44 (W1) :W147-W153
[5]   Thrombin and hemin as central factors in the mechanisms of intracerebral hemorrhage-induced secondary brain injury and as potential targets for intervention [J].
Babu, Ranjith ;
Bagley, Jacob H. ;
Di, Chunhui ;
Friedm, Allan H. ;
Adamson, Cory .
NEUROSURGICAL FOCUS, 2012, 32 (04)
[6]   Metabolic Induction of Trained Immunity through the Mevalonate Pathway [J].
Bekkering, Siroon ;
Arts, Rob J. W. ;
Novakovic, Boris ;
Kourtzelis, Ioannis ;
van der Heijden, Charlotte D. C. C. ;
Li, Yang ;
Popa, Calin D. ;
ter Horst, Rob ;
van Tuijl, Julia ;
Netea-Maier, Romana T. ;
de Veerdonk, Frank L. van ;
Chavakis, Triantafyllos ;
Joosten, Leo A. B. ;
van der Meer, Jos W. M. ;
Stunnenberg, Henk ;
Riksen, Niels P. ;
Netea, Mihai G. .
CELL, 2018, 172 (1-2) :135-+
[7]   High salt reduces the activation of IL-4-and IL-13-stimulated macrophages [J].
Binger, Katrina J. ;
Gebhardt, Matthias ;
Heinig, Matthias ;
Rintisch, Carola ;
Schroeder, Agnes ;
Neuhofer, Wolfgang ;
Hilgers, Karl ;
Manzel, Arndt ;
Schwartz, Christian ;
Kleinewietfeld, Markus ;
Voelkl, Jakob ;
Schatz, Valentin ;
Linker, Ralf A. ;
Lang, Florian ;
Voehringer, David ;
Wright, Mark D. ;
Hubner, Norbert ;
Dechend, Ralf ;
Jantsch, Jonathan ;
Titze, Jens ;
Mueller, Dominik N. .
JOURNAL OF CLINICAL INVESTIGATION, 2015, 125 (11) :4223-4238
[8]   Macrophage function in tissue repair and remodeling requires IL-4 or IL-13 with apoptotic cells [J].
Bosurgi, Lidia ;
Cao, Y. Grace ;
Cabeza-Cabrerizo, Mar ;
Tucci, Andrea ;
Hughes, Lindsey D. ;
Kong, Yong ;
Weinstein, Jason S. ;
Licona-Limon, Paula ;
Schmid, Edward T. ;
Pelorosso, Facundo ;
Gagliani, Nicola ;
Craft, Joseph E. ;
Flavell, Richard A. ;
Ghosh, Sourav ;
Rothlin, Carla V. .
SCIENCE, 2017, 356 (6342) :1072-+
[9]   VOLUME OF INTRACEREBRAL HEMORRHAGE - A POWERFUL AND EASY-TO-USE PREDICTOR OF 30-DAY MORTALITY [J].
BRODERICK, JP ;
BROTT, TG ;
DULDNER, JE ;
TOMSICK, T ;
HUSTER, G .
STROKE, 1993, 24 (07) :987-993
[10]   Nr4a1-Dependent Ly6Clow Monocytes Monitor Endothelial Cells and Orchestrate Their Disposal [J].
Carlin, Leo M. ;
Stamatiades, Efstathios G. ;
Auffray, Cedric ;
Hanna, Richard N. ;
Glover, Leanne ;
Vizcay-Barrena, Gema ;
Hedrick, Catherine C. ;
Cook, H. Terence ;
Diebold, Sandra ;
Geissmann, Frederic .
CELL, 2013, 153 (02) :362-375
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