Single-cell transcriptomics reveal distinctive patterns of fibroblast activation in heart failure with preserved ejection fraction

TY1, a synthetic non-coding RNA (ncRNA) bioinspired by small Y RNAs abundant in extracellular vesicles (EVs), decreases cGAS/STING activation in myocardial infarction and thereby attenuates inflammation. Motivated by the concept that heart failure with preserved ejection fraction (HFpEF) is a systemic inflammatory disease, we tested TY1 in a murine model of HFpEF. Intravenous TY1, packaged in a transfection reagent, reversed the cardiac and systemic manifestations of HFpEF in two-hit obese-hypertensive mice, without inducing weight loss. The effects of TY1 were specific, insofar as they were not reproduced by a control RNA of the same nucleotide content but in scrambled order. TY1 consistently suppressed myocardial stress-induced MAP kinase signaling, as well as downstream inflammatory, fibrotic, and hypertrophic gene pathways in heart tissue. TY1 not only prevented but actually reversed key pathological processes underlying HFpEF, with no evidence of toxicity. Most noteworthy from a practical perspective, the effects of intravenous TY1 were reproduced by feeding HFpEF mice an oral micellar formulation of TY1. As the prototype for a novel class of ncRNA drugs which target cell stress, TY1 exhibits exceptional disease-modifying bioactivity in HFpEF.

show abstract

A cross-study transcriptional patient map of heart failure defines conserved multicellular coordination in cardiac remodeling

Lanzer,

Ramirez Flores,

Liñares Blanco

et al. 2024

Preprint

View full text Add to dashboard Cite

Heart failure (HF) is characterized by severely reduced cardiac function and tissue remodeling, driven by complex multicellular regulatory processes. Extensive studies have generated molecular profiles at both bulk and single-cell levels; however, systematic integration that describes tissue-wide changes as a function of cell type coordination remains challenging. This disconnect hampers our understanding of the complex multicellular interactions driving heart failure, limiting our ability to translate molecular insights into actionable therapeutic strategies. Here, we integrated bulk and single-cell transcriptional profiles from cardiac tissues of HF and control patients across 25 studies, covering 1,524 individuals and seven cell-types, to delineate consensus multicellular transcriptional changes associated with cardiac remodeling. Our analyses revealed conserved cellular coordination events involving fibrotic, metabolic, inflammatory, and hypertrophic mechanisms, with fibroblasts playing a central role in predicting cardiomyocyte stress. Further analysis of fibroblast populations suggested that their activation in HF represents a broad phenotypic shift rather than solely accumulating distinct cell states. The integration of bulk and single-cell data within our data collection indicated that transcriptional responses to HF across cell types occur independently of tissue composition. Mapping independent data into our consensus programs demonstrated that recovery after left ventricular assist device implantation aligns with molecular recovery, highlighting the clinical relevance of the multicellular molecular state. Overall, our work synthesizes independent cardiac transcriptomics studies and makes the conserved HF associated insights available, establishing a reference for detailed exploration of HF-related multicellular molecular events.

show abstract

Single-cell transcriptomics reveal distinctive patterns of fibroblast activation in heart failure with preserved ejection fraction

Cited by 3 publications

References 111 publications

High-resolution DNA methylation changes reveal biomarkers of heart failure with preserved ejection fraction versus reduced ejection fraction

High-resolution DNA methylation changes reveal biomarkers of heart failure with preserved ejection fraction versus reduced ejection fraction

Intravenous and oral administration of the synthetic RNA drug, TY1, reverses heart failure with preserved ejection fraction in mice

A cross-study transcriptional patient map of heart failure defines conserved multicellular coordination in cardiac remodeling

Contact Info

Product

Resources

About