Hypoxia-driven microRNA-27b underlies pathologic cardiac endoreplication in heart disease
Summary
Heart disease is characterized by stress-induced endoreplication preceding pathological cardiomyocyte overgrowth, yet the upstream regulatory mechanisms linking tissue hypoxia to aberrant cellular growth remain incompletely defined. Here, we identify cardiac hypoxia as a key determinant of endoreplication through activation of a hypoxia-inducible factor-1 alpha-microRNA regulatory axis that converges on mitochondrial energetic control. We show that stress-induced activation of hypoxia-indu
Content
# Hypoxia-driven microRNA-27b underlies pathologic cardiac endoreplication in heart disease
*Published: 2026 May 14*
Heart disease is characterized by stress-induced endoreplication preceding
pathological cardiomyocyte overgrowth, yet the upstream regulatory mechanisms
linking tissue hypoxia to aberrant cellular growth remain incompletely defined.
Here, we identify cardiac hypoxia as a key determinant of endoreplication
through activation of a hypoxia-inducible factor-1 alpha-microRNA regulatory
axis that converges on mitochondrial energetic control. We show that
stress-induced activation of hypoxia-inducible factor-1 alpha drives
transcriptional induction of microRNA-27b-5p, which directly represses the ATP
synthase subunit ATP5A1, resulting in impaired mitochondrial ATP synthesis and
accumulation of intra-mitochondrial ADP. Elevated ADP serves as a rate-limiting
cofactor for one-carbon metabolism, promoting formate production and de novo
purine biosynthesis, thereby enabling pathological endoreplication and
cardiomyocyte hypertrophic growth. Genetic gain- and loss-of-function studies
targeting hypoxia-inducible factor-1 alpha, microRNA-27b, and ATP5A1 across
multiple mouse models of cardiac stress, together with correlative analyses of
human cardiac biopsies, establish a conserved and causal relationship between
dysregulated mitochondrial energetics and pathological cardiac remodeling.
Inhibition of microRNA-27b-5p attenuates established cardiac hypertrophy,
improves cardiac function, and suppresses stress-induced multinucleation in
vivo. Leveraging this mechanistic insight, we identify the clinically approved
antifolate compound methotrexate as an effective inhibitor of stress-induced
cardiac endoreplication and pathological hypertrophy in preclinical models.
Collectively, these findings define a druggable hypoxia-driven metabolic pathway
linking mitochondrial ATP homeostasis to pathological cardiomyocyte growth and
suggest therapeutic opportunities for targeting maladaptive cardiac remodeling.
DOI: 10.1038/s41392-026-02656-x