Differential immunological signature at the culprit site distinguishes acute coronary syndrome with intact from acute coronary syndrome with ruptured fibrous cap: results from the prospective translational OPTICO-ACS study

David M Leistner, Nicolle Kränkel, Denitsa Meteva, Youssef S Abdelwahed, Claudio Seppelt, Barbara E Stähli, Himanshu Rai, Carsten Skurk, Alexander Lauten, Hans-Christian Mochmann, Georg Fröhlich, Ursula Rauch-Kröhnert, Eduardo Flores, Matthias Riedel, Lara Sieronski, Sylvia Kia, Elisabeth Strässler, Arash Haghikia, Fabian Dirks, Julia K Steiner, Dominik N Mueller, Hans-Dieter Volk, Jens Klotsche, Michael Joner, Peter Libby, Ulf Landmesser, David M Leistner, Nicolle Kränkel, Denitsa Meteva, Youssef S Abdelwahed, Claudio Seppelt, Barbara E Stähli, Himanshu Rai, Carsten Skurk, Alexander Lauten, Hans-Christian Mochmann, Georg Fröhlich, Ursula Rauch-Kröhnert, Eduardo Flores, Matthias Riedel, Lara Sieronski, Sylvia Kia, Elisabeth Strässler, Arash Haghikia, Fabian Dirks, Julia K Steiner, Dominik N Mueller, Hans-Dieter Volk, Jens Klotsche, Michael Joner, Peter Libby, Ulf Landmesser

Abstract

Aims: Acute coronary syndromes with intact fibrous cap (IFC-ACS), i.e. caused by coronary plaque erosion, account for approximately one-third of ACS. However, the underlying pathophysiological mechanisms as compared with ACS caused by plaque rupture (RFC-ACS) remain largely undefined. The prospective translational OPTICO-ACS study programme investigates for the first time the microenvironment of ACS-causing culprit lesions (CL) with intact fibrous cap by molecular high-resolution intracoronary imaging and simultaneous local immunological phenotyping.

Methods and results: The CL of 170 consecutive ACS patients were investigated by optical coherence tomography (OCT) and simultaneous immunophenotyping by flow cytometric analysis as well as by effector molecule concentration measurements across the culprit lesion gradient (ratio local/systemic levels). Within the study cohort, IFC caused 24.6% of ACS while RFC-ACS caused 75.4% as determined and validated by two independent OCT core laboratories. The IFC-CL were characterized by lower lipid content, less calcification, a thicker overlying fibrous cap, and largely localized near a coronary bifurcation as compared with RFC-CL. The microenvironment of IFC-ACS lesions demonstrated selective enrichment in both CD4+ and CD8+ T-lymphocytes (+8.1% and +11.2%, respectively, both P < 0.05) as compared with RFC-ACS lesions. T-cell-associated extracellular circulating microvesicles (MV) were more pronounced in IFC-ACS lesions and a significantly higher amount of CD8+ T-lymphocytes was detectable in thrombi aspirated from IFC-culprit sites. Furthermore, IFC-ACS lesions showed increased levels of the T-cell effector molecules granzyme A (+22.4%), perforin (+58.8%), and granulysin (+75.4%) as compared with RFC plaques (P < 0.005). Endothelial cells subjected to culture in disturbed laminar flow conditions, i.e. to simulate coronary flow near a bifurcation, demonstrated an enhanced adhesion of CD8+T cells. Finally, both CD8+T cells and their cytotoxic effector molecules caused endothelial cell death, a key potential pathophysiological mechanism in IFC-ACS.

Conclusions: The OPTICO-ACS study emphasizes a novel mechanism in the pathogenesis of IFC-ACS, favouring participation of the adaptive immune system, particularly CD4+ and CD8+ T-cells and their effector molecules. The different immune signatures identified in this study advance the understanding of coronary plaque progression and may provide a basis for future development of personalized therapeutic approaches to ACS with IFC.

Trial registration: The study was registered at clinicalTrials.gov (NCT03129503).

Keywords: Acute coronary syndrome; CD8+; Endothelial erosion; Optical coherence tomography; Plaque rupture; Shear stress; T cells.