Abstract
AbstractAtherosclerotic cardiovascular disease, a chronic inflammatory condition of multifactorial etiology, is the leading cause of death worldwide. The concept of ‘bacterial persistence’ has been proposed as one of several contributing factors to this disease. We hypothesized that the infectious agent(s) found at the site of the atheroma may be dormant but perpetuate virulence in response to host defense and other physiological triggers. In this study, we sought to identify the source of persistent infection in human atherosclerotic plaque and define how pathogen virulence and host defenses mediate plaque vulnerability. Whole genome sequencing (WGS) was used to identify bacteria from pure cultures obtained from atherosclerotic tissues of living subjects diagnosed with more than 70% occlusion of the carotid artery undergoing carotid endarterectomy (CE). WGS identified the predominant species as S. pasteuri (Spv) in all CE isolates grown in pure culture except one isolate which was identified as B. licheniformis. All S. pasteuri isolates (Spvs) were found to contain genes for widespread virulence, invasion, and intracellular resistance. As macrophages (Mφs) play a decisive role at all stages of this disease we treated mouse Mφs (RAW 264.7) with Spvs. While all Spvs tested demonstrated their ability to survive phagocytosis, the highly virulent Spvs also activated Mφs and induced trans-endothelial cell migration of these cells which was mediated via the CC chemokine CCL1 and its receptor CCR8. In conclusion, we show that Spvs are found in CE plaques, have the capacity to survive phagocytosis and induce the transmigration of Mφs across an endothelial barrier in a CCL1-CCR8 dependent process. These findings highlight the significance of carotid vessels as a reservoir for S. pasteuri, a pathogen found in products used routinely in human consumption; this may explain how microbial pathogenicity modulates plaque vulnerability in atherosclerosis.
Publisher
Cold Spring Harbor Laboratory