Effect of sex chromosomes versus hormones in neonatal lung injury
Sandra L. Grimm, Xiaoyu Dong, Yuhao Zhang, Alexandre F. Carisey, Arthur P. Arnold, Bhagavatula Moorthy, Cristian Coarfa, Krithika Lingappan
Sandra L. Grimm, Xiaoyu Dong, Yuhao Zhang, Alexandre F. Carisey, Arthur P. Arnold, Bhagavatula Moorthy, Cristian Coarfa, Krithika Lingappan
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Research Article Pulmonology

Effect of sex chromosomes versus hormones in neonatal lung injury

Abstract

The main mechanisms underlying sexually dimorphic outcomes in neonatal lung injury are unknown. We tested the hypothesis that hormone- or sex chromosome–mediated mechanisms interact with hyperoxia exposure to impact injury and repair in the neonatal lung. To distinguish sex differences caused by gonadal hormones versus sex chromosome complement (XX versus XY), we used the Four Core Genotypes (FCG) mice and exposed them to hyperoxia (95% FiO2, P1–P4: saccular stage) or room air. This model generates XX and XY mice that each have either testes (with Sry, XXM, or XYM) or ovaries (without Sry, XXF, or XYF). Lung alveolarization and vascular development were more severely impacted in XYM and XYF compared with XXF and XXM mice. Cell cycle–related pathways were enriched in the gonadal or chromosomal females, while muscle-related pathways were enriched in the gonadal males, and immune-response–related pathways were enriched in chromosomal males. Female gene signatures showed a negative correlation with human patients who developed bronchopulmonary dysplasia (BPD) or needed oxygen therapy at 28 days. These results demonstrate that chromosomal sex — and not gonadal sex — impacted the response to neonatal hyperoxia exposure. The female sex chromosomal complement was protective and could mediate sex-specific differences in the neonatal lung injury.

Authors

Sandra L. Grimm, Xiaoyu Dong, Yuhao Zhang, Alexandre F. Carisey, Arthur P. Arnold, Bhagavatula Moorthy, Cristian Coarfa, Krithika Lingappan

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Figure 3

Arrest in angiogenesis and lung macrophages after hyperoxia exposure is differentially impacted by chromosomal and gonadal sex in neonatal mice.

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Arrest in angiogenesis and lung macrophages after hyperoxia exposure is ...
IHC and quantitation of pulmonary microvessels was done by immunostaining for endothelial-specific vWF (n = 5–6 mice per group) in room air or hyperoxia (95% FiO2, P1–P4) in XXF, XXM, XYF, and XYM mice at P21. (A and B) Representative stained sections at ×20 (A) and ×40 magnification (B). Arrows point to brown-staining vessels. (C) Quantitative analyses showing number of vessels per high-power field (×20) in lungs of FCG neonatal mice. IHC and quantitation of macrophages was done by immunostaining for F4/80 (n = 5–6 mice per group) in room air or hyperoxia (95% FiO2, P1–P4) in XXF, XXM, XYF, and XYM mice at P21. (D and E) Representative stained sections at ×20 (D) and ×40 magnification (E). Arrows point to brown-staining macrophages. (F) Quantitative analyses showing number of macrophages per high-power field (×20) in lungs of FCG neonatal mice. Data are shown as mean ± SD from 5–6 individual animals. Statistical analysis was performed using 3-way ANOVA to assess the effect of treatment, chromosomal sex, and gonadal sex, as well as the interactions between the independent variables. Significant differences between room air and hyperoxia within genotype are indicated by *P <0.05 and ***P <0.001. Significant differences between hyperoxia-exposed mice between different genotypes are indicated by ##P < 0.01 and ###P < 0.001. Scale bars: 50 μm.