Pairing of single-cell RNA analysis and T cell antigen receptor profiling indicates breakdown of T cell tolerance checkpoints in atherosclerosis.
Zhihua WangXi ZhangShu LuChuankai ZhangZhe MaRui SuYuanfang LiTing SunYutao LiMingyang HongXinyi DengMohammad Rafiee MonjeziMichael HristovSabine SteffensDonato SantovitoKlaus DornmairKlaus LeyChristian WeberSarajo K MohantaAndreas J R HabenichtChangjun YinPublished in: Nature cardiovascular research (2023)
Atherosclerotic plaques form in the inner layer of arteries triggering heart attacks and strokes. Although T cells have been detected in atherosclerosis, tolerance dysfunction as a disease driver remains unexplored. Here we examine tolerance checkpoints in atherosclerotic plaques, artery tertiary lymphoid organs and lymph nodes in mice burdened by advanced atherosclerosis, via single-cell RNA sequencing paired with T cell antigen receptor sequencing. Complex patterns of deteriorating peripheral T cell tolerance were observed being most pronounced in plaques followed by artery tertiary lymphoid organs, lymph nodes and blood. Affected checkpoints included clonal expansion of CD4 + , CD8 + and regulatory T cells; aberrant tolerance-regulating transcripts of clonally expanded T cells; T cell exhaustion; T reg -TH 17 T cell conversion; and dysfunctional antigen presentation. Moreover, single-cell RNA-sequencing profiles of human plaques revealed that the CD8 + T cell tolerance dysfunction observed in mouse plaques was shared in human coronary and carotid artery plaques. Thus, our data support the concept of atherosclerosis as a bona fide T cell autoimmune disease targeting the arterial wall.
Keyphrases
- single cell
- rna seq
- lymph node
- regulatory t cells
- high throughput
- cardiovascular disease
- endothelial cells
- heart failure
- oxidative stress
- coronary artery
- coronary artery disease
- multiple sclerosis
- type diabetes
- early stage
- machine learning
- sentinel lymph node
- metabolic syndrome
- neoadjuvant chemotherapy
- adipose tissue
- artificial intelligence
- pluripotent stem cells
- electronic health record
- aortic valve
- locally advanced
- aortic stenosis