Infection history imprints prolonged changes to the epigenome, transcriptome and function of Kupffer cells

Liver macrophages fulfill various homeostatic functions and represent an essential line of defense against pathogenic insults. However, it remains unclear whether a history of infectious disease in the liver leads to long-term alterations to the liver macrophage compartment. We utilized a curable mo...

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Published in:Journal of hepatology 2024-12, Vol.81 (6), p.1023-1039
Main Authors: Musrati, Mohamed Amer, Stijlemans, Benoit, Azouz, Abdulkader, Kancheva, Daliya, Mesbahi, Sarah, Hadadi, Eva, Lebegge, Els, Ali, Leen, De Vlaminck, Karen, Scheyltjens, Isabelle, Vandamme, Niels, Zivalj, Maida, Assaf, Naela, Elkrim, Yvon, Ahmidi, Ilham, Huart, Camille, Lamkanfi, Mohamed, Guilliams, Martin, De Baetselier, Patrick, Goriely, Stanislas, Movahedi, Kiavash, Van Ginderachter, Jo A.
Format: Article
Language:English
Subjects:
Animals
Disease Models, Animal
epigenetic remodeling
Epigenome
Kupffer Cells - metabolism
Liver - metabolism
Liver - parasitology
liver inflammation
macrophage niche
Macrophages - metabolism
Macrophages - parasitology
Mice
ontogeny
tissue-resident macrophage
trained immunity
Transcriptome
Trypanosoma
Trypanosoma brucei brucei - genetics
Trypanosomiasis - parasitology
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Summary:Liver macrophages fulfill various homeostatic functions and represent an essential line of defense against pathogenic insults. However, it remains unclear whether a history of infectious disease in the liver leads to long-term alterations to the liver macrophage compartment. We utilized a curable model of parasitic infection invoked by the protozoan parasite Trypanosoma brucei brucei to investigate whether infection history can durably reshape hepatic macrophage identity and function. Employing a combination of fate mapping, single-cell CITE-sequencing, single-nuclei multiome analysis, epigenomic analysis, and functional assays, we studied the alterations to the liver macrophage compartment during and after the resolution of infection. We show that T. brucei brucei infection alters the composition of liver-resident macrophages, leading to the infiltration of monocytes that differentiate into various infection-associated macrophage populations with divergent transcriptomic profiles. Whereas infection-associated macrophages disappear post-resolution of infection, monocyte-derived macrophages engraft in the liver, assume a Kupffer cell (KC)-like profile and co-exist with embryonic KCs in the long-term. Remarkably, the prior exposure to infection imprinted an altered transcriptional program on post-resolution KCs that was underpinned by an epigenetic remodeling of KC chromatin landscapes and a shift in KC ontogeny, along with transcriptional and epigenetic alterations in their niche cells. This reprogramming altered KC functions and was associated with increased resilience to a subsequent bacterial infection. Our study demonstrates that a prior exposure to a parasitic infection induces trained immunity in KCs, reshaping their identity and function in the long-term. Although the liver is frequently affected during infections, and despite housing a major population of resident macrophages known as Kupffer cells (KCs), it is currently unclear whether infections can durably alter KCs and their niche cells. Our study provides a comprehensive investigation into the long-term impact of a prior, cured parasitic infection, unveiling long-lasting ontogenic, epigenetic, transcriptomic and functional changes to KCs as well as KC niche cells, which may contribute to KC remodeling. Our data suggest that infection history may continuously reprogram KCs throughout life with potential implications for subsequent disease susceptibility in the liver, influencing preventive and t
ISSN:0168-8278
1600-0641
1600-0641
DOI:10.1016/j.jhep.2024.07.007