Ariane Schumski1,2, Almudena Ortega-Gómez1,2, Kanin Wichapong3, Carla Winter1, Patricia Lemnitzer1, Joana R Viola1, Mayra Pinilla-Vera4, Eduardo Folco5, Victor Solis-Mezarino6, Moritz Völker-Albert6, Sanne L Maas2, Chang Pan1, Laura Perez Olivares1, Janine Winter1, Tilman Hackeng3, Mikael C I Karlsson7, Tanja Zeller8,9, Axel Imhof10, Rebecca M Baron4, Gerry A F Nicolaes3, Peter Libby5, Lars Maegdefessel2,11, Frits Kamp12, Martin Benoit13, Yvonne Döring1,14, Oliver Soehnlein1,2,15. 1. Institute for Cardiovascular Prevention (IPEK), LMU Munich Hospital, Germany (A.S., A.O.-G., C.W., P. Lemnitzer, J.R.V., C.P., L.P.O., J.W., Y.D., O.S.). 2. German Center for Cardiovascular Research (DZHK), partner site Munich Heart Alliance (MHA), Munich, Germany (A.S., A.O.-G., S.L.M., L.M., O.S.). 3. Department of Biochemistry, CARIM, University Maastricht, The Netherlands (K.W., T.H., G.A.F.N.). 4. Division of Pulmonary and Critical Care Medicine (M.P.-V., R.M.B.), Brigham and Women's Hospital, Harvard Medical School, Boston, MA. 5. Division of Cardiovascular Medicine (E.F., P. L.), Brigham and Women's Hospital, Harvard Medical School, Boston, MA. 6. EpiQMAx GmbH, Planegg-Martinsried, Germany (V.S.-M., M.V.-A.). 7. Department of Microbiology, Tumor and Cell Biology (M.C.I.K.), Karolinska Institute, Stockholm, Sweden. 8. Department of General and Interventional Cardiology, University Heart Center Hamburg, Germany (T.Z.). 9. German Center for Cardiovascular Research (DZHK), Partner Site Hamburg, Lübeck, Kiel Hamburg, Germany (T.Z.). 10. BMC, Chromatin Proteomics Group, Department of Molecular Biology (A.I.), LMU München, Germany. 11. Department of Vascular and Endovascular Surgery, Technical University Munich, Germany (L.M.). 12. BMC, Metabolic Biochemistry (F.K.), LMU München, Germany. 13. Center for Nano Science (CeNS), Department of Physics, Munich, Germany (M.B.). 14. Division of Angiology, Swiss Cardiovascular Centre, Inselspital, Bern University Hospital, University of Bern, Switzerland (Y.D.). 15. Department of Physiology and Pharmacology (FyFa) (O.S.), Karolinska Institute, Stockholm, Sweden.
Abstract
BACKGROUND: Acute infection is a well-established risk factor of cardiovascular inflammation increasing the risk for a cardiovascular complication within the first weeks after infection. However, the nature of the processes underlying such aggravation remains unclear. Lipopolysaccharide derived from Gram-negative bacteria is a potent activator of circulating immune cells including neutrophils, which foster inflammation through discharge of neutrophil extracellular traps (NETs). Here, we use a model of endotoxinemia to link acute infection and subsequent neutrophil activation with acceleration of vascular inflammation Methods: Acute infection was mimicked by injection of a single dose of lipopolysaccharide into hypercholesterolemic mice. Atherosclerosis burden was studied by histomorphometric analysis of the aortic root. Arterial myeloid cell adhesion was quantified by intravital microscopy. RESULTS: Lipopolysaccharide treatment rapidly enhanced atherosclerotic lesion size by expansion of the lesional myeloid cell accumulation. Lipopolysaccharide treatment led to the deposition of NETs along the arterial lumen, and inhibition of NET release annulled lesion expansion during endotoxinemia, thus suggesting that NETs regulate myeloid cell recruitment. To study the mechanism of monocyte adhesion to NETs, we used in vitro adhesion assays and biophysical approaches. In these experiments, NET-resident histone H2a attracted monocytes in a receptor-independent, surface charge-dependent fashion. Therapeutic neutralization of histone H2a by antibodies or by in silico designed cyclic peptides enables us to reduce luminal monocyte adhesion and lesion expansion during endotoxinemia. CONCLUSIONS: Our study shows that NET-associated histone H2a mediates charge-dependent monocyte adhesion to NETs and accelerates atherosclerosis during endotoxinemia.
BACKGROUND: Acute infection is a well-established risk factor of cardiovascular inflammation increasing the risk for a cardiovascular complication within the first weeks after infection. However, the nature of the processes underlying such aggravation remains unclear. Lipopolysaccharide derived from Gram-negative bacteria is a potent activator of circulating immune cells including neutrophils, which foster inflammation through discharge of neutrophil extracellular traps (NETs). Here, we use a model of endotoxinemia to link acute infection and subsequent neutrophil activation with acceleration of vascular inflammation Methods: Acute infection was mimicked by injection of a single dose of lipopolysaccharide into hypercholesterolemic mice. Atherosclerosis burden was studied by histomorphometric analysis of the aortic root. Arterial myeloid cell adhesion was quantified by intravital microscopy. RESULTS: Lipopolysaccharide treatment rapidly enhanced atherosclerotic lesion size by expansion of the lesional myeloid cell accumulation. Lipopolysaccharide treatment led to the deposition of NETs along the arterial lumen, and inhibition of NET release annulled lesion expansion during endotoxinemia, thus suggesting that NETs regulate myeloid cell recruitment. To study the mechanism of monocyte adhesion to NETs, we used in vitro adhesion assays and biophysical approaches. In these experiments, NET-resident histone H2a attracted monocytes in a receptor-independent, surface charge-dependent fashion. Therapeutic neutralization of histone H2a by antibodies or by in silico designed cyclic peptides enables us to reduce luminal monocyte adhesion and lesion expansion during endotoxinemia. CONCLUSIONS: Our study shows that NET-associated histone H2a mediates charge-dependent monocyte adhesion to NETs and accelerates atherosclerosis during endotoxinemia.
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