2023
Trained immunity induced by high‐salt diet impedes stroke recovery
Lin T, Jiang D, Chen W, Lin J, Zhang X, Chen C, Hsu C, Lai L, Chen P, Yang K, Sansing L, Chang C. Trained immunity induced by high‐salt diet impedes stroke recovery. EMBO Reports 2023, 24: e57164. PMID: 37965920, PMCID: PMC10702837, DOI: 10.15252/embr.202357164.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsDietImmunity, InnateInflammationMacrophagesMiceSodium Chloride, DietaryStrokeTrained ImmunityConceptsInnate immune memoryMonocyte-derived macrophagesStroke recoveryInflammatory responseBone marrowImmune memoryHigh-salt dietCause of morbidityInitial inflammatory responsePotential therapeutic targetLoss of Nr4a1Stroke outcomeStroke brainIntracerebral hemorrhageBrain recoverySterile inflammationHealthy miceTissue injurySevere formTherapeutic targetAlternative activationImmune primingReparative functionsProgenitor cellsNR4A family
2021
Divergent Functions of Tissue-Resident and Blood-Derived Macrophages in the Hemorrhagic Brain
Chang CF, Goods BA, Askenase MH, Beatty HE, Osherov A, DeLong JH, Hammond MD, Massey J, Landreneau M, Love JC, Sansing LH. Divergent Functions of Tissue-Resident and Blood-Derived Macrophages in the Hemorrhagic Brain. Stroke 2021, 52: 1798-1808. PMID: 33840225, PMCID: PMC8085165, DOI: 10.1161/strokeaha.120.032196.Peer-Reviewed Original ResearchConceptsMonocyte-derived macrophagesIntracerebral hemorrhageT cell proliferationCore transcriptional programDifferential gene expressionDistinct transcriptional signaturesBone marrow-derived macrophagesAntigen-specific T cell proliferationTranscriptional programsCD4 T cell proliferationLongitudinal transcriptomic analysisVivo phagocytosis assaysTranscriptomic analysisDivergent functionsMarrow-derived macrophagesMHCII genesTissue-resident microgliaAntigen-presenting capabilityAutologous blood injectionGene expressionPrimary microglia culturesInnate immune cellsPhagocytosis of debrisTranscriptional signatureBlood-derived macrophagesLongitudinal transcriptomics define the stages of myeloid activation in the living human brain after intracerebral hemorrhage
Askenase MH, Goods BA, Beatty HE, Steinschneider AF, Velazquez SE, Osherov A, Landreneau MJ, Carroll SL, Tran TB, Avram VS, Drake RS, Gatter GJ, Massey JA, Karuppagounder SS, Ratan RR, Matouk CC, Sheth KN, Ziai WC, Parry-Jones AR, Awad IA, Zuccarello M, Thompson RE, Dawson J, Hanley DF, Love JC, Shalek AK, Sansing LH, Barrer S, MacKenzie L, Jonczak K, Bussinger P, Nakaji P, Wright S, Honea N, Zomorodi A, James M, Yeh E, Galicich W, Bergman T, France K, Leiphart J, Ramesh S, Brennan T, Huang J, Ziai W, White M, Camarata P, Abraham M, Gorup J, Reimer R, Freeman W, Williams C, Edwards E, Pollack A, Terry J, Shoen A, Jahromi B, Maas M, Yip B, Amidei C, Muñoz L, Lopez G, Holtz R, Gupta G, Rybinnik I, Moccio M, Lovick D, Brion B, Titus K, Jallo J, Rincon F, Pigott K, Boyden L, Dougherty J, Harrigan M, Miller D, Nelson L, Thompson G, Rajajee V, Pandey A, Ball R, Carlson A, Tran H, Alchbli A, James R, Jerde A, Taussky P, Ansari S, Neate C, Martinez J, Letsinger J, Fagatele L, Eaquinto C, Matouk C, Sheth K, Sansing L, Ryall L, Kunze K, Mampre D, Jasak S, Abdul-Rahim A, Abou-Hamden A, Abraham M, Ahmed A, Alba C, Aldrich E, Ali H, Altschul D, Amin-Hanjani S, Anderson C, Anderson D, Ansari S, Antezana D, Ardelt A, Arikan F, Awad R, Baguena M, Baker A, Barrer S, Barzo P, Becker K, Bergman T, Betz J, Bistran-Hall A, Boström A, Braun J, Brindley P, Broaddus W, Brown R, Buki A, Bulters D, Camarata P, Cao B, Cao Y, Carhuapoma J, Carlson A, Caron J, Carrion-Penagos J, Chalela J, Chang T, Chicoine M, Chorro I, Chowdhry S, Cobb C, Corral L, Csiba L, Davies J, Dawson J, Díaz A, Derdeyn C, Diringer M, Dlugash R, Dodd R, Ecker R, Economas T, Enriquez P, Ezer E, Fan Y, Feng H, Franz D, Freeman W, Fusco M, Galicich W, Gandhi D, Gelea M, Goldstein J, Gonzalez A, Grabarits C, Greenberg S, Gregson B, Gress D, Gu E, Gupta G, Hall C, Hanley D, Hao Y, Harnof S, Harrigan M, Hernandez F, Hoesch R, Hoh B, Houser J, Hu R, Huang J, Huang Y, Hussain M, Insinga S, Jadhav A, Jaffe J, Jahromi B, Jallo J, James M, James R, Janis S, Jankowitz B, Jeon E, Jichici D, Jonczak K, Jonker B, Karlen N, Kase C, Keric N, Kerz T, Kitagawa R, Knopman J, Koenig C, Krishnamurthy S, Kumar A, Kureshi I, Laidlaw J, Lakhanpal A, Lane K, Latorre J, LeDoux D, Lees K, Leifer D, Leiphart J, Lenington S, Li Y, Lopez G, Lovick D, Lumenta C, Luo J, Maas M, MacDonald J, MacKenzie L, Madan V, Majkowski R, Major O, Malhorta R, Malkoff M, Mangat H, Maswadeh A, Matouk C, Mayo S, McArthur K, McBee N, McCaul S, Medow J, Mendelow A, Mezey G, Mighty J, Miller D, Mitchell P, Mohan K, Money P, Mould W, Muir K, Muñoz L, Nakaji P, Nee A, Nekoovaght-Tak S, Nyquist P, O’Kane R, Okasha M, O'Kelly C, Ostapkovich N, Pandey A, Parry-Jones A, Patel H, Perla K, Pollack A, Polster S, Pouratian N, Quinn T, Rajajee V, Reddy K, Rehman M, Reimer R, Rincon F, Rosenblum M, Rybinnik I, Sanchez B, Sansing L, Sarabia R, Schneck M, Schuerer L, Schul D, Schweitzer J, Seder D, Seyfried D, Sheth K, Spiotta A, Stadnik A, Stechison M, Sugar E, Szabo K, Tamayo G, Tanczos K, Taussky P, Teitelbaum J, Terry J, Testai F, Thomas K, Thompson C, Thompson G, Thompson R, Torner J, Tran H, Tucker K, Ullman N, Ungar L, Unterberg A, Varelas P, Vargas N, Vatter H, Venkatasubramanian C, Vermillion K, Vespa P, Vollmer D, Wang W, Wang Y, Wang Y, Wen J, Whitworth L, Willis B, Wilson A, Wolfe S, Wrencher M, Wright S, Xu Y, Yanase L, Yenokyan G, Yi X, Yu Z, Ziai W, Zomorodi A, Zuccarello M. Longitudinal transcriptomics define the stages of myeloid activation in the living human brain after intracerebral hemorrhage. Science Immunology 2021, 6 PMID: 33891558, PMCID: PMC8252865, DOI: 10.1126/sciimmunol.abd6279.Peer-Reviewed Original ResearchConceptsIntracerebral hemorrhageHypoxia-inducible factorMyeloid activationBrain injuryImmune responseAnti-inflammatory circuitsSubtypes of strokeAnti-inflammatory factorsInflammatory gene expressionPositive patient outcomesMonocytes/macrophagesDynamics of inflammationAcute sterile injuryLongitudinal transcriptional profilingHuman brainNeurological recoveryMyeloid responseProinflammatory profileImmune resolutionPatient cohortImmune factorsClinical trialsPatient outcomesSterile injuryProstaglandin E
2020
Response by Chang and Sansing to Letter Regarding Article, “Bexarotene Enhances Macrophage Erythrophagocytosis and Hematoma Clearance in Experimental Intracerebral Hemorrhage”
Chang CF, Sansing LH. Response by Chang and Sansing to Letter Regarding Article, “Bexarotene Enhances Macrophage Erythrophagocytosis and Hematoma Clearance in Experimental Intracerebral Hemorrhage”. Stroke 2020, 51: e88. PMID: 32299318, PMCID: PMC8059296, DOI: 10.1161/strokeaha.120.029256.Peer-Reviewed Original Research
2019
Bexarotene Enhances Macrophage Erythrophagocytosis and Hematoma Clearance in Experimental Intracerebral Hemorrhage
Chang CF, Massey J, Osherov A, Angenendt da Costa LH, Sansing LH. Bexarotene Enhances Macrophage Erythrophagocytosis and Hematoma Clearance in Experimental Intracerebral Hemorrhage. Stroke 2019, 51: 612-618. PMID: 31826730, PMCID: PMC7135897, DOI: 10.1161/strokeaha.119.027037.Peer-Reviewed Original ResearchConceptsIntracerebral hemorrhageBexarotene treatmentFunctional recoveryHematoma clearanceRetinoid X receptor agonistExperimental intracerebral hemorrhageX receptor agonistMacrophage TNF productionMarrow-derived macrophagesNeurological recoveryNeurobehavioral recoveryNeurological deficitsAutologous bloodBrain recoveryHematoma volumeReceptor agonistTherapeutic effectMacrophage expressionTNF productionMouse modelVivo phagocytosisMacrophage phenotypeFlow cytometryHistological analysisErythrocyte metabolites