The pentose phosphate pathway mediates hyperoxia-induced lung vascular dysgenesis and alveolar simplification in neonates
Jiannan Gong, Zihang Feng, Abigail L. Peterson, Jennifer F. Carr, Xuexin Lu, Haifeng Zhao, Xiangming Ji, You-Yang Zhao, Monique E. De Paepe, Phyllis A. Dennery, Hongwei Yao
Jiannan Gong, Zihang Feng, Abigail L. Peterson, Jennifer F. Carr, Xuexin Lu, Haifeng Zhao, Xiangming Ji, You-Yang Zhao, Monique E. De Paepe, Phyllis A. Dennery, Hongwei Yao
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Research Article Pulmonology

The pentose phosphate pathway mediates hyperoxia-induced lung vascular dysgenesis and alveolar simplification in neonates

Abstract

Dysmorphic pulmonary vascular growth and abnormal endothelial cell (EC) proliferation are paradoxically observed in premature infants with bronchopulmonary dysplasia (BPD), despite vascular pruning. The pentose phosphate pathway (PPP), a metabolic pathway parallel to glycolysis, generates NADPH as a reducing equivalent and ribose 5-phosphate for nucleotide synthesis. It is unknown whether hyperoxia, a known mediator of BPD in rodent models, alters glycolysis and the PPP in lung ECs. We hypothesized that hyperoxia increases glycolysis and the PPP, resulting in abnormal EC proliferation and dysmorphic angiogenesis in neonatal mice. To test this hypothesis, lung ECs and newborn mice were exposed to hyperoxia and allowed to recover in air. Hyperoxia increased glycolysis and the PPP. Increased PPP, but not glycolysis, caused hyperoxia-induced abnormal EC proliferation. Blocking the PPP reduced hyperoxia-induced glucose–derived deoxynucleotide synthesis in cultured ECs. In neonatal mice, hyperoxia-induced abnormal EC proliferation, dysmorphic angiogenesis, and alveolar simplification were augmented by nanoparticle-mediated endothelial overexpression of phosphogluconate dehydrogenase, the second enzyme in the PPP. These effects were attenuated by inhibitors of the PPP. Neonatal hyperoxia augments the PPP, causing abnormal lung EC proliferation, dysmorphic vascular development, and alveolar simplification. These observations provide mechanisms and potential metabolic targets to prevent BPD-associated vascular dysgenesis.

Authors

Jiannan Gong, Zihang Feng, Abigail L. Peterson, Jennifer F. Carr, Xuexin Lu, Haifeng Zhao, Xiangming Ji, You-Yang Zhao, Monique E. De Paepe, Phyllis A. Dennery, Hongwei Yao

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Figure 2

Hyperoxic exposure increases the PPP in cultured lung ECs.

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Hyperoxic exposure increases the PPP in cultured lung ECs. (A–E) MFLM-91...
(AE) MFLM-91U cells (A and E) and primary LMVECs (BD) were exposed to hyperoxia for 24 hours and then cultured in normoxia for 24 hours (refers to O2) unless specifically mentioned. (A) [3-13C]lactate was measured by the NMR when cells were incubated with [1,2-13C]glucose (20 mM) for 24 hours during air recovery phase. n = 4 per group. (B) Western blot was performed to determine levels of PGD and G6PD proteins. O2 w/o rec refers hyperoxic exposure for 24 hours without air recovery, while O2 refers hyperoxic exposure for 24 hours, followed by air recovery for 24 hours. n = 6 in air, n = 7 in hyperoxia without air recovery, and n = 3 in hyperoxia with air recovery. (C) NADPH levels were measured using a commercially available kit. n = 6 in air and n = 9 in hyperoxia. (D) Levels of ribulose 5-phosphate, reduced and reduced/oxidized glutathione were determined through metabolomics analysis. n = 4 in air and n = 6 in hyperoxia. (E) Ratio of [3-13C]lactate to [2,3-13C]lactate was calculated based on results from Figure 1D and A. n = 4 per group. Data are expressed as mean ± SEM. *P < 0.05, **P < 0.01, ***P < 0.001 versus air using 1-tailed t test (A, C, D, and E) or ANOVA followed by Tukey-Kramer test (B).