Transcriptional heterogeneity of fibroblasts is a hallmark of the aging heart

Aging is a major risk factor for cardiovascular disease. Although the impact of aging has been extensively studied, little is known regarding the aging processes in cells of the heart. Here we analyzed the transcriptomes of hearts of 12-week-old and 18-month-old mice by single-nucleus RNA-sequencing. Among all cell types, aged fibroblasts showed most significant differential gene expression, increased RNA dynamics, and network entropy. Aged fibroblasts exhibited significantly changed expression patterns of inflammatory, extracellular matrix organization angiogenesis, and osteogenic genes. Functional analyses indicated deterioration of paracrine signatures between fibroblasts and endothelial cells in old hearts. Aged heart-derived fibroblasts had impaired endothelial cell angiogenesis and autophagy and augmented proinflammatory response. In particular, expression of Serpine1 and Serpine2 were significantly increased and secreted by old fibroblasts to exert antiangiogenic effects on endothelial cells, an effect that could be significantly prevented by using neutralizing antibodies. Moreover, we found an enlarged subpopulation of aged fibroblasts expressing osteoblast genes in the epicardial layer associated with increased calcification. Taken together this study provides system-wide insights and identifies molecular changes of aging cardiac fibroblasts, which may contribute to declined heart function

IL-11 is a crucial determinant of cardiovascular fibrosis

Fibrosis is a final common pathology in cardiovascular disease1. In the heart, fibrosis causes mechanical and electrical dysfunction1,2 and in the kidney, it predicts the onset of renal failure3. Transforming growth factor β1 (TGFB1) is the principal pro-fibrotic factor4,5 but its inhibition is associated with side effects due to its pleiotropic roles6,7. We hypothesised that downstream effectors of TGFB1 in fibroblasts could be attractive therapeutic targets and lack upstream toxicities. Using integrated imaging-genomics analyses of primary human fibroblasts, we found that Interleukin 11 (IL11) upregulation is the dominant transcriptional response to TGFB1 exposure and required for its profibrotic effect. IL11 and its receptor (IL11RA) are expressed specifically in fibroblasts where they drive non-canonical, ERK-dependent autocrine signalling that is required for fibrogenic protein synthesis. In mice, fibroblast-specific Il11 transgene expression or Il11 injection causes heart and kidney fibrosis and organ failure whereas genetic deletion of Il11ra1 is protective against disease. Thus, inhibition of IL11 prevents fibroblast activation across organs and species in response to a range of important pro-fibrotic stimuli. These data reveal a central role of IL11 in fibrosis and we propose inhibition of IL11 as a new therapeutic strategy to treat fibrotic diseases

IL-11 is a crucial determinant of cardiovascular fibrosis

10.1038/nature24676Nature5527683110-115NATU

FACS isolation of endothelial cells and pericytes from mouse brain microregions

The vasculature is emerging as a key contributor to brain function during neurodevelopment and in mature physiological and pathological states. The brain vasculature itself also exhibits regional heterogeneity, highlighting the need to develop approaches for purifying cells from different microregions. Previous approaches for isolation of endothelial cells and pericytes have predominantly required transgenic mice and large amounts of tissue, and have resulted in impure populations. In addition, the prospective purification of brain pericytes has been complicated by the fact that widely used pericyte markers are also expressed by other cell types in the brain. Here, we describe the detailed procedures for simultaneous isolation of pure populations of endothelial cells and pericytes directly from adult mouse brain microregions using fluorescence-activated cell sorting (FACS) with antibodies against CD31 (endothelial cells) and CD13 (pericytes). This protocol is scalable and takes ∼5 h, including microdissection of the region of interest, enzymatic tissue dissociation, immunostaining, and FACS. This protocol allows the isolation of brain vascular cells from any mouse strain under diverse conditions; these cells can be used for multiple downstream applications, including in vitro and in vivo experiments, and transcriptomic, proteomic, metabolomic, epigenomic, and single-cell analysis