Inês Pinto Coelho scite author profile

Nonalcoholic fatty liver disease (NAFLD) is rapidly becoming the most prevalent cause of liver disease worldwide and afflicts adults and children as currently associated with obesity and insulin resistance. Even though lately some advances have been made to elucidate the mechanism and causes of the disease much remains unknown about NAFLD. The aim of this paper is to discuss the present knowledge regarding the pathogenesis of the disease aiming at the initial steps of NAFLD development, when inflammation impinges on fat liver deposition. At this stage, the Kupffer cells attain a prominent role. This knowledge becomes subsequently relevant for the development of future diagnostic, prevention, and therapeutic options for the management of NAFLD.

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Trem-2 Promotes Emergence of Restorative Macrophages and Endothelial Cells During Recovery From Hepatic Tissue Damage

Coelho

Duarte

Barros

et al. 2021

Front. Immunol.

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Macrophages are pivotal in mounting liver inflammatory and tissue repair responses upon hepatic injury, showing remarkable functional plasticity. The molecular mechanisms determining macrophage transition from inflammatory to restorative phenotypes in the damaged liver remain unclear. Using mouse models of acute (APAP) and chronic (CCl4) drug-induced hepatotoxic injury we show that the immune receptor Trem-2 controls phenotypic shifts of liver macrophages and impacts endothelial cell differentiation during tissue recovery. Trem-2 gene ablation led to a delayed re-population of Kupffer cells correlating with deterred resolution of hepatic damage following acute and chronic injury. During tissue recovery, we found that macrophages transitioning to Kupffer cells expressed high levels of Trem-2. Acquisition of the transition phenotype was associated with a unique transcriptomic profile denoting strong responsiveness to oxidative stress and downmodulation of the pro-inflammatory phenotype, which was not observed in absence of Trem-2. During tissue recovery, lack of Trem-2 favored accumulation of a liver-damage associated endothelial cell population (LDECs), whose transcriptional program was compatible with endothelial de-differentiation. Accordingly, LDECs precursor potential is supported by the downregulation of surface endothelial cell markers and by striking in vitro morphological changes towards typical endothelial cells. In conclusion, we found that the dynamics of liver macrophages in response to liver injury are critically controlled by Trem-2 and this regulation is interlinked with the de-differentiation of endothelial cells and heightened liver pathology. We propose that Trem-2 promotes the transition from pro-inflammatory to tissue repair phase by driving the acquisition of restorative properties in phagocytic macrophages.

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Trem-2 promotes emergence of restorative macrophages and endothelial cells during recovery from hepatic tissue damage

Coelho

Duarte

Barros

et al. 2019

Preprint

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Macrophages are pivotal in mounting liver inflammatory and tissue repair reactions upon hepatic injury showing remarkable functional plasticity. Nevertheless, the molecular mechanisms determining macrophage transition from inflammatory to restorative phenotypes in the damaged liver remain unclear. Using mouse models of acute (APAP) or chronic (CCl4) drug-induced hepatotoxic injury we show that the immune receptor Trem-2 controls phenotypic shifts in liver macrophages and impacts endothelial cell differentiation during tissue recovery.Trem-2 gene ablation led to delayed re-population of Kupffer cells correlating with deterred resolution of hepatic damage following acute and chronic injury. We found that during tissue recovery macrophages in transition to the Kupffer cell compartment expressed high levels of Trem-2. Acquisition of the transition phenotype was associated with an unique transcriptomic profile denoting strong responsiveness to oxidative stress and downmodulation of the pro-inflammatory phenotype, which was not observed in absence of Trem-2.During tissue recovery lack of Trem-2 favored accumulation of a liver-damage associated endothelial cell population (LDECs) engaged in a transcriptional program compatible with endothelial de-differentiation. Accordingly, LDECs precursor potential is supported by the downregulation of surface endothelial cell markers and striking in vitro morphological changes towards typical endothelial cells.In conclusion, we found that the dynamics of liver macrophages in response to liver injury is critically controlled by Trem-2 and is interlinked with the de-differentiation of endothelial cells and heightened liver pathology. We propose that Trem-2 promotes the transition from the pro-inflammatory to the tissue repair phase by driving the acquisition of restorative properties of phagocytic macrophages.

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Dipeptidyl Peptidase‐4 Is a Pro‐Recovery Mediator During Acute Hepatotoxic Damage and Mirrors Severe Shifts in Kupffer Cells

Duarte

Coelho

Holovanchuk

et al. 2018

Hepatology Communications

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Dipeptidyl peptidase‐4 (DPP‐4 or clusters of differentiation [CD]26) is a multifunctional molecule with established roles in metabolism. Pharmacologic inhibition of DPP‐4 is widely used to improve glycemic control through regulation of the incretin effect. Colaterally, CD26/DPP‐4 inhibition appears to be beneficial in many inflammatory conditions, namely in delaying progression of liver pathology. Nevertheless, the exact implications of CD26/DPP‐4 enzymatic activity in liver dysfunction remain unclear. In this work, we investigated the involvement of CD26/DPP‐4 in experimental mouse models of induced hepatocyte damage that severely impact Kupffer cell (KC) populations. Liver dysfunction was evaluated in CD26 knockout (KO) and B6 wild‐type mice during acute liver damage induced by acetaminophen, chronic liver damage induced by carbon tetrachloride, and KC‐depleting treatment with clodronate‐loaded liposomes. We found that necrosis resolution after hepatotoxic injury was delayed in CD26KO mice and in B6 mice treated with the CD26/DPP‐4 inhibitor sitagliptin, suggesting that DPP‐4 enzymatic activity plays a role in recovering from acute liver damage. Interestingly, the severe KC population reduction in acute and chronic liver injury was concomitant with increased CD26/DPP‐4 serum levels. Remarkably, both chronic liver damage and noninflammatory depletion of KCs by clodronate liposomes were marked by oscillation in CD26/DPP‐4 serum activity that mirrored the kinetics of liver KC depletion/recovery. Conclusion:CD26/DPP‐4 enzymatic activity contributes to necrosis resolution during recovery from acute liver injury. Serum CD26/DPP‐4 is elevated when severe perturbations are imposed on KC populations, regardless of patent liver damage. We propose that serum CD26/DPP‐4 is a potential systemic surrogate marker of severe impairments in the KC population imposed by clinical and subclinical liver conditions.

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