Trained Immunity Causes Myeloid Cell Hypercoagulability

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2025 Mar 7

PMID 40053582

Authors

Aisling M Rehill

Sean McCluskey

Anna E Ledwith

Tristram A J Ryan

Betul Unlu

Gemma Leon

Hugo Charles-Messance

Edmund H Gilbert

Paula Klavina

Emily A Day

Judith Coppinger

Jamie M OSullivan

Corrina McMahon

James S ODonnell

Annie M Curtis

Luke A J ONeill

Frederick J Sheedy

Roger J S Preston

Affiliations

Soon will be listed here.

Abstract

The pathogenic basis for increased thrombotic risk in individuals with inflammatory diseases is poorly understood. Myeloid cell "trained immunity" describes persistent innate immune cell memory arising from prior exposure to an inflammatory stimulus, leading to an enhanced immune response to subsequent unrelated stimuli. We identify enhanced myeloid cell prothrombotic activity as a maladaptive consequence of trained immunity. Lipopolysaccharide (LPS) stimulation of macrophages trained previously with β-glucan or heme exhibited significantly enhanced procoagulant activity compared to macrophages stimulated with LPS alone, which was mediated by enhanced acid sphingomyelinase-mediated tissue factor decryption. Furthermore, splenic monocytes isolated from β-glucan-trained mice revealed enhanced procoagulant activity up to 4 weeks after β-glucan administration compared to monocytes from control mice over the same time period. Moreover, hematopoietic progenitor cells and bone marrow interstitial fluid from β-glucan-trained mice had enhanced procoagulant activity compared to control mice. Trained immunity and associated metabolic perturbations may therefore represent an opportunity for targeted intervention in immunothrombotic disease development.

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