Neonatal hyperoxia inhibits proliferation and survival of atrial cardiomyocytes by suppressing fatty acid synthesis
Ethan David Cohen, … , Gloria S. Pryhuber, Michael A. O’Reilly
Ethan David Cohen, … , Gloria S. Pryhuber, Michael A. O’Reilly
Published January 28, 2021
Citation Information: JCI Insight. 2021;6(5):e140785. https://doi.org/10.1172/jci.insight.140785.
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Research Article Cardiology

Neonatal hyperoxia inhibits proliferation and survival of atrial cardiomyocytes by suppressing fatty acid synthesis

Abstract

Preterm birth increases the risk for pulmonary hypertension and heart failure in adulthood. Oxygen therapy can damage the immature cardiopulmonary system and may be partially responsible for the cardiovascular disease in adults born preterm. We previously showed that exposing newborn mice to hyperoxia causes pulmonary hypertension by 1 year of age that is preceded by a poorly understood loss of pulmonary vein cardiomyocyte proliferation. We now show that hyperoxia also reduces cardiomyocyte proliferation and survival in the left atrium and causes diastolic heart failure by disrupting its filling of the left ventricle. Transcriptomic profiling showed that neonatal hyperoxia permanently suppressed fatty acid synthase (Fasn), stearoyl-CoA desaturase 1 (Scd1), and other fatty acid synthesis genes in the atria of mice, the HL-1 line of mouse atrial cardiomyocytes, and left atrial tissue explanted from human infants. Suppressing Fasn or Scd1 reduced HL-1 cell proliferation and increased cell death, while overexpressing these genes maintained their expansion in hyperoxia, suggesting that oxygen directly inhibits atrial cardiomyocyte proliferation and survival by repressing Fasn and Scd1. Pharmacologic interventions that restore Fasn, Scd1, and other fatty acid synthesis genes in atrial cardiomyocytes may, thus, provide a way of ameliorating the adverse effects of supplemental oxygen on preterm infants.

Authors

Ethan David Cohen, Min Yee, George A. Porter Jr., Erin Ritzer, Andrew N. McDavid, Paul S. Brookes, Gloria S. Pryhuber, Michael A. O’Reilly

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Figure 6

Suppression of fatty acid synthesis contributes to reduced HL-1 cell proliferation in hyperoxia.

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Suppression of fatty acid synthesis contributes to reduced HL-1 cell pro...
(A) qPCR for Fasn (left) and Scd1 (right) in HL-1 cells grown in room air or hyperoxia for 24 hours (white and blue, respectively) or 48 hours (yellow and red, respectively). (B) Numbers of HL-1 cells grown in room air (white circles) and hyperoxia (gray squares) for 48 hours relative to their density at 0 hours. (C and E) qPCR for Fasn (C) and Scd1 (E) in HL-1 cells transfected with Fasn and Scd1 siRNAs. Controls were transfected with nontargeting (NT) siRNA. (D and F) Numbers of HL-1 cells transfected with control siRNA (white circles in D and F) and Fasn (Gray squares in D) or Scd1 (Gray squares in F) siRNAs and grown for 48 hours in room air relative to 0 hrs. (G) HL-1 cells transfected with NT, Fasn, and Scd1 siRNAs, grown in room air for 22 hours and treated with EdU for 2 hours before staining. Graph shows percentages of EdU+ cells. (H) HL-1 cells transfected with NT, Fasn, and Scd1 siRNAs were grown in room air for 48 hours, stained with PI, and imaged. Graph shows numbers of PI+ NT, Fasn, and Scd1 siRNA transfected cells. (A, C, and E) n = 4 transfections per condition. Each time/condition: (G and H), n = 12. (B, D, and F) Error bars show 95% CI; lines and P values are results of linear regressions. (A, C, E, G, and H) Box plots are median, second quartiles, and third quartile; whiskers indicate range, and markers show individual replicates. P values are from unpaired 2-tailed t tests (C and E) or 1-way ANOVA with Holm-Sidak corrections (A, G, and H).