Discovery of drugs to treat cytokine storm-induced cardiac dysfunction using human cardiac organoids
Type
PreprintAuthor/s
Mills, Richard JHumphrey, Sean J
Fortuna, Patrick RJ
Quaife-Ryan, Gregory A
Mehdiabadi, Neda R
Devilée, Lynn
Voges, Holly K
Reynolds, Liam T
Krumeich, Sophie
Mathieson, Ellen
Griffen, Brendan
Titmarsh, Drew
Porrello, Enzo R
Smyth, Mark J
Engwerda, Christian R
MacDonald, Kelli PA
Bald, Tobias
James, David E
Hudson, James E
Abstract
SUMMARY SARS-CoV2 infection leads to cardiac injury and dysfunction in 20-30% of hospitalized patients 1 and higher rates of mortality in patients with pre-existing cardiovascular disease 2,3 . Inflammatory factors released as part of the ‘cytokine storm’ are thought to play a ...
See moreSUMMARY SARS-CoV2 infection leads to cardiac injury and dysfunction in 20-30% of hospitalized patients 1 and higher rates of mortality in patients with pre-existing cardiovascular disease 2,3 . Inflammatory factors released as part of the ‘cytokine storm’ are thought to play a critical role in cardiac dysfunction in severe COVID-19 patients 4 . Here we use human cardiac organoids combined with high sensitivity phosphoproteomics and single nuclei RNA sequencing to identify inflammatory targets inducing cardiac dysfunction. This state-of-the-art pipeline allowed rapid deconvolution of mechanisms and identification of putative therapeutics. We identify a novel interferon-γ driven BRD4 (bromodomain protein 4)-fibrosis/iNOS axis as a key intracellular mediator of inflammation-induced cardiac dysfunction. This axis is therapeutically targetable using BRD4 inhibitors, which promoted full recovery of function in human cardiac organoids and prevented severe inflammation and death in a cytokine-storm mouse model. The BRD inhibitor INCB054329 was the most efficacious, and is a prime candidate for drug repurposing to attenuate cardiac dysfunction and improve COVID-19 mortality in humans.
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See moreSUMMARY SARS-CoV2 infection leads to cardiac injury and dysfunction in 20-30% of hospitalized patients 1 and higher rates of mortality in patients with pre-existing cardiovascular disease 2,3 . Inflammatory factors released as part of the ‘cytokine storm’ are thought to play a critical role in cardiac dysfunction in severe COVID-19 patients 4 . Here we use human cardiac organoids combined with high sensitivity phosphoproteomics and single nuclei RNA sequencing to identify inflammatory targets inducing cardiac dysfunction. This state-of-the-art pipeline allowed rapid deconvolution of mechanisms and identification of putative therapeutics. We identify a novel interferon-γ driven BRD4 (bromodomain protein 4)-fibrosis/iNOS axis as a key intracellular mediator of inflammation-induced cardiac dysfunction. This axis is therapeutically targetable using BRD4 inhibitors, which promoted full recovery of function in human cardiac organoids and prevented severe inflammation and death in a cytokine-storm mouse model. The BRD inhibitor INCB054329 was the most efficacious, and is a prime candidate for drug repurposing to attenuate cardiac dysfunction and improve COVID-19 mortality in humans.
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Date
2020Funding information
Medical Research Council
Australian Research Council
National Health and Medical Research Council
Licence
OtherFaculty/School
Faculty of Medicine and Health, Sydney Medical SchoolShare