New insights into the development of radiation-induced cardiac damage using a mouse model

Background The improvement of anticancer-therapy results in a greater amount of long-term survivors after radiotherapy. Therefore, the understanding of cardiotoxicity after irradiation is of increasing importance. Long-term adverse cardiovascular events may become evident years or decades after radiotherapy. The relative contribution of irradiation in relation to other cancer treatments can often only be estimated. Recent experimental and clinical evidence suggests that cardiovascular symptoms, including exertional dyspnoea, may be caused by heart failure with preserved ejection fraction (HFpEF), which remains incompletely understood in patients after radiation therapy. Purpose We aim to characterize the development of radiation-induced cardiomyopathy and elucidate underlying patho-mechanisms. Methods Mice received a single dose of whole thorax irradiation (12.5 Gy) and were sacrificed at 1 and 3 days or 3, 6, 12, 16, 20 and 25–30 weeks. Endothelial cells and immune cells at different time points were quantified using flow cytometry (FACS). Structural changes and localization of endothelial cell damage was imaged using light-sheet fluorescence microscopy (LSFM) with CD31 staining. Development of fibrosis was determined using qRT-PCR (fibronectin and TGFβ), western blot (collagen-1,α-smooth muscle) and (immune-)histological analyses. Functional analyses were conducted using echocardiography and pressure-volume-(PV-)catheterization. Results Endothelial damage was determined by significant reduction of CD31 expression in mouse hearts 6 weeks after irradiation compared to sham-treated control mice using FACS analyses. LSFM showed structural changes especially in the edge zone of left ventricle presented as less densely CD31 stained regions. Additionally, we investigated cardiac immune cell response regarding innate and adaptive immunity, showing specific response to tissue damage at different time points. Invasion of monocytes started 6 weeks after irradiation and highest level of monocytes and macrophages was measured at 12 weeks. Regarding cardiac long-term damage, myocardial fibrosis was detected on RNA- and protein-level as well as in histological analyses with significant changes 20 weeks after chest irradiation. This could be correlated with echocardiographic parameters for diastolic dysfunction (elevated isovolumic relaxation time/mitral valve deceleration time). Also functional reserve of irradiated mice was reduced, investigated by measurement of cardiac output and stroke volume after dobutamine injection in PV-catheterization. Conclusion We described a novel time-dependent endothelial cell damage and immune cell response after thoracic irradiation in mice, which could also be imaged using LSFM. Characterization of long-term damage showed cardiac fibrosis correlating with diastolic dysfunction and reduced contractile reserve. Furthermore, therapeutic approaches will be investigated using the established mouse model. FUNDunding Acknowledgement Type of funding sources: Public Institution(s). Main funding source(s): Dr. S.M. Mrotzek acknowledges the following funding source: IFORES research grant from the Medical Faculty, University Duisburg-Essen, Germany.