Neutrophil Peptidylarginine Deiminase 4 is Essential for Detrimental Age-related Cardiac Remodeling & Dysfunction in Mice

Abstract

AbstractAimsWe aimed to study the long-term effect of neutrophils on cardiac health during the process of natural aging. We hypothesized that neutrophil PAD4, via its role in neutrophil extracellular trap (NET) formation, is involved in myocardial remodeling and cardiac fibrosis development, resulting in turn in impaired cardiac function.Methods and resultsWe generated mice with deletion of Padi4, a NET-essential gene, under the neutrophil-specific promoter S100A8 (PAD4fl/flMRP8Cre+). These mice and their littermate controls were aged for two years (coinciding with approximately 70 years of age in humans; the age at which HF is the number one cause of hospitalization), after which cardiac function and remodeling were evaluated. We performed a comprehensive echocardiography analysis including both structural and functional parameter measurements. Deletion of PAD4 in neutrophils resulted in a protection against both systolic, and diastolic dysfunction. Interestingly, these mice showed protection against age induced fibrosis, detected as through the absence of cardiac collagen deposition. To explore this further, cardiac gene expression and plasma cytokine levels were evaluated. Here we saw a clear impact of PAD4-deficiency on cardiac neutrophil recruitment, with both cardiac genes as well as plasma cytokines involved in neutrophil recruitment being downregulated in aged PAD4fl/flMRP8Cre+ animals in comparison to littermate PAD4fl/fl controls, including decreased plasma levels of C-X-C ligand 1 (CXCL1).ConclusionOur data confirms neutrophil PAD4 involvement in heart failure progression by promoting cardiac remodeling, leading to cardiac dysfunction with old age. We saw that the deletion of PAD4 specifically in neutrophils had an influence on the CXCL1-CXCR2 axis, which is known to be involved in HF development.Translational perspectiveIn the developed world, an estimated 2% of the population lives with heart failure (HF). HF can be viewed as an upcoming pandemic, which is only expected to increase due to the aging of the global population. Therefore, research in HF development and progression are needed to establish new avenues for treatment and improved therapies. In our study, we were able to show the contribution of neutrophil PAD4 to HF pathogenesis, providing new supporting evidence for the involvement of NETs in detrimental cardiac remodeling.